Rods Contribute to Visual Behavior in Larval Zebrafish.

Purpose: Although zebrafish rods begin to develop as early as 2 days postfertilization (dpf), they are not deemed anatomically mature and functional until 15 to 21 dpf. A recent study detected a small electroretinogram (ERG) from rods in a cone mutant called no optokinetic response f (nof) at 5 dpf, suggesting that young rods are functional. Whether they can mediate behavioral responses in larvae is unknown.
Methods: We first confirmed rod function by measuring nof ERGs under photopic and scotopic illumination at 6 dpf. We evaluated the role of rods in visual behaviors using two different assays: the visual-motor response (VMR) and optokinetic response (OKR). We measured responses from wild-type (WT) larvae and nof mutants under photopic and scotopic illuminations at 6 dpf.
Results: Nof mutants lacked a photopic ERG. However, after prolonged dark adaptation, they displayed scotopic ERGs. Compared with WT larvae, the nof mutants displayed reduced VMRs. The VMR difference during light onset gradually diminished with decreased illumination and became nearly identical at lower light intensities. Additionally, light-adapted nof mutants did not display an OKR, whereas dark-adapted nof mutants displayed scotopic OKRs. Conclusions: Because the nof mutants lacked a photopic ERG but displayed scotopic ERGs after dark adaptation, the mutants clearly had functional rods. WT larvae and the nof mutants displayed comparable scotopic light-On VMRs and scotopic OKRs after dark adaptation, suggesting that these responses were driven primarily by rods. Together, these observations indicate that rods contribute to zebrafish visual behaviors as early as 6 dpf.

In the zebrafish eye, progenitor cells mainly withdraw from the cell cycle at 48 hours postfertilization (hpf) to form photoreceptor precursors in the outer nuclear layer of the retina. Some of these precursors begin to differentiate into rods at 36 to 50 hpf in a specialized ventral patch region of the retina. They form outer segments and express rhodopsin (rho).– Subsequently, rods slowly increase in numbers throughout the retina., Their synaptic terminals can be detected at approximately 62 hpf., By 68 hpf, the retina is mature enough to initiate a visually evoked startle response. Shortly after 72 hpf, the larvae also display an optokinetic response (OKR) and an electroretinogram (ERG). Even though rods initially differentiate at early developmental stages, their role in mediating vision and visual behaviors has been controversial. For example, rods were deemed not anatomically mature until 15 to 20 days postfertilization (dpf), and not contributing to vision until this stage. The first detectable physiological rod response by ERG recordings was also reported to appear between 15 and 21 dpf. This uncertainty in rod function during early development has somewhat limited the utility of the zebrafish model for studying rod diseases and behavior.

Because the earlier ERG studies were performed in wild-type (WT) zebrafish, it is possible that rod responses might have been obscured by cone responses, which dominate early visual responses. To circumvent this issue, a recent study isolated rod responses in larvae as early as 5 dpf by measuring ERGs in a cone mutant called no optokinetic response f (nof). The nof mutant carries a point mutation, which introduces a premature stop codon in gnat2 (guanine nucleotide binding protein [G protein], alpha transducing activity polypeptide 2), a gene encoding the alpha subunit of cone transducin. This mutation leads to undetectable transducin protein in the nof retina up to 2 months of age. Even though the transducin is undetectable in nof retina, retinal morphology appears normal. The nof mutation also does not cause a secondary effect in the phototransduction pathway as evidenced by normal levels of opsins and RGS9 (regulator of G protein signaling 9), and normal activity of phosphodiesterase and guanylyl cyclase. The nof mutation, however, greatly affects cone function. For example, with normal photopic light stimuli (4.41 × 104 photons/µm2 at 590 nm for 10 ms), no electrophysiological responses can be elicited from nof cones at 2 to 3.5 months. However, with very bright lights (1.3 × 107 photons/µm2/s at 590 nm for 2 s), it is possible to elicit a small, slow response from some nof cones that appears to result from the release of Ca2+ into the cell cytoplasm from internal stores. These observations indicate that nof cones in young adults do not respond to normal photopic illumination. However, nof rods appear unaffected by the mutation and remain functionally intact. For example, single nof rods at 2 to 3.5 months have normal light sensitivity to 10-ms flashes compared with WT rods, suggesting their responses are not altered by the absence of functional cones. Using the nof mutant, rod function has been detected in zebrafish larvae as early as 5 dpf. In that study, Moyano et al. evaluated the effects of nicotine on cone and rod b-waves in the ERG. They detected small a- and b-wave responses from dark-adapted nof larvae at 5 dpf under scotopic illumination. These observations suggest that rods in young larvae are functional and contribute to the ERG. Nonetheless, it is not known whether these young rods contribute to visual behavioral responses. In this study, we first measured ERGs under both photopic and scotopic illumination in WT and nof mutants at 6 dpf to confirm rod function in young larvae. We found nof mutants lacked a photopic ERG, indicating that they lacked cone function. However, after dark adaptation, these mutants displayed scotopic ERGs over 5 log units of light attenuation. This indicates that their rods were functional at this stage.

We then tested the role of rods in driving visual behaviors of young zebrafish larvae with two different assays: the visual-motor response (VMR) and OKR. The VMR is a visual startle response displayed by zebrafish larvae with normal vision at both light onset (light-On) and offset (light-Off)., It can be detected in WT larvae as early as 3 dpf. This response has been used by us and others to study the effect of mutations,– toxic chemicals, and therapeutic compounds on zebrafish vision. It has also been used by us to evaluate the difference in response between different WT strains.,, In a typical VMR assay, zebrafish larvae are presented with a series of light-On and light-Off stimuli. Each light-On stimulus is preceded by a dark phase, during which rods are dark-adapted for the upcoming light onset. Similarly, each light-Off stimulus is preceded by a light phase, during which rod responses are reduced or saturated, depending on the intensity of light illumination. A complication regarding the VMR is that extraocular photoreceptors (EOPs) found in hypothalamus and pineal gland can contribute to the response, especially when bright lights are used., However, the EOP contribution to the VMR has a delayed onset and never shows the sharp initial peak characteristic of both the light-On and light-Off responses., The EOP contribution can be differentiated from the photoreceptor contribution by analyzing the early phase of the VMR in the first few seconds, and by comparing the response with that obtained from an eyeless chokh/rx3 mutant, which only possesses EOPs but not ocular photoreceptors.

The OKR is a visual behavior triggered in normal WT larvae by a rotating drum with stripe gratings.,, Each OKR consists of a smooth eye movement along the direction of drum rotation followed by a rapid saccade back. It can be detected in zebrafish larvae as early as 3 dpf and robustly starting at 5 dpf. The VMR and OKR comprise key visual responses in zebrafish larvae and are well suited for evaluating rod contribution to larval visual function. In this study, we optimized these visual behaviors for measuring rod response in zebrafish larvae. We also used the nof mutants to isolate rod function. We found that the nof mutants displayed a VMR and OKR as early as 6 dpf under scotopic conditions. Therefore rods likely contribute to visual behaviors in young zebrafish larvae.

Materials and Methods

Fish Maintenance and Breeding

Adult fish were maintained according to standard procedures in a 14/10-hour light/dark cycle in the fish facility.– The nof/gnat2 (nof) mutant line was obtained from Susan Brockerhoff at the University of Washington. The homozygous mutant embryos were obtained by crossing heterozygous parents because the mutants do not survive to adulthood. The control embryos were obtained from the genotyped WT siblings of the heterozygous parents. The nof mutants were identified at 5 dpf using the OKR. The chokh/rx3 mutant line was obtained from Jessica Miller at Harvard University. Their homozygous embryos do not develop eyes due to a mutation in the Rx3 homeodomain-containing transcription factor. They were obtained by crossing heterozygous parents. Because the chokh/rx3 mutants lack eyes, they were easily identified at 2 dpf by morphologic observation. All embryos and larvae were raised in E3 medium in a 28°C incubator with a 14/10 hour light/dark cycle. They were inspected and medium replaced every day. Unhealthy embryos were discarded and not used for any experiment. All protocols were approved by Purdue Animal Care and Use Committee and adhered to the ARVO statement for the Use of Animals in Ophthalmic and Vision Research.

OKR Assay

In this study, a custom-made OKR apparatus was used based on the basic specifications previously reported. To conduct OKR measurements, the larvae were partially immobilized in 3% methylcellulose in a 35-mm Petri dish. The dish was placed in the center of a circular drum with 20° black and white vertical stripes attached on the inner surface. The stripes were illuminated by a Fiber Lite M1-150 illuminator (Dolan-Jenner Industries, Boxborough, MA, USA). Light intensity was measured by a Thorlabs PM100 optical power meter (Thorlabs, Newton, NJ, USA). Without attenuation (log I = 0), the irradiance was 1.1 × 103 µW/cm2 at 500 nm at the level of Petri dish. To achieve lower light intensities, neutral-density filters were placed in the light path to attenuate the light. During OKR measurements, the rotation speed of the drum was set at three to four revolutions per minute. In response to such stripe rotation, normal larvae displayed characteristic OKR eye movements, including smooth pursuits and saccades.

ERG Recording

ERGs were recorded from isolated larval eyes as described. The eyes were maintained in Ringer's solution that flowed continuously over the preparation and was maintained at pH 7.8 by gassing the solution by 97% O2 and 3% CO2. The glass recording electrode had an 8- to 12-µm tip and contained a chloride-coated silver wire. The electrode was filled with Ringer's solution and inserted into the anterior chamber to record the summed outer retinal cell responses. The reference electrode was placed in the agarose covering the preparation stage. A 500-ms full-field light flash was used under photopic lighting condition to ensure b- and d-wave separation, whereas a 200-ms flash was used under scotopic conditions because no d-wave is elicited under these conditions. For photopic conditions, zebrafish larvae were adapted to light at approximately 200 µW/cm2 at 500 nm for at least 2 hours. For scotopic recordings, animals were dark-adapted for at least 2 hours, followed by the eye preparation using dim red light at 670 nm under a dissecting microscope fitted with infrared light intensifiers. The stimulus light source was a 100W halogen bulb with a light intensity of 5.3 × 104 µW/cm2 at 500 nm (log I = 0). Light was attenuated using Wratten neutral-density filters. Light readings were determined using Thorlabs PM100 optical power meter (Thorlabs). The ERG response was amplified, and low-pass filtered at 300 Hz. At least three recordings were averaged to obtain an ERG trace. All recordings were acquired using the LabVIEW program (National Instruments, Austin, TX, USA). Data analyses were conducted using IGOR Pro (WaveMetrics, Portland, OR, USA) custom-made software.

VMR Assay

The VMR assay was designed based on published reports. Larvae were individually arranged in a 96-plate (Whatman 96-squarewell UNIPLATE, GE Healthcare Bio-Sciences, Marlborough, MA, USA) inside a ZebraBox system (ViewPoint Life Sciences, Lyon, France). They were isolated from environmental light and stimulated by white light emitted by a light source placed from the bottom of the 96-well plate. The larval movement was recorded by an infrared sensitive camera at a rate of 30 frames per second under 850-nm infrared illumination, not perceived by the larvae. Before experiments, larvae in the 96-well plate were dark-adapted in the ZebraBox system for 3.5 hours. The actual test consisted of three consecutive trials of light onset (light-On) and light offset (light-Off) periods, each period lasting for 30 minutes. In other words, the larvae were exposed to either light or dark for 30 minutes before the next light change. The light change (on or off) was abrupt and set at different light intensities. The light intensity was measured by an ILT950 spectroradiometer (International Light Technologies, Peabody, MA, USA) from each well of an empty 96-well plate placed on top of the light source. At the maximum output intensity (100%), the average irradiance at 500 nm was 3.77 µW/cm2 (SD = 0.54) (log I = 0). Lower light intensities were achieved by adjusting the output light intensity of the Zebrabox by 2 log units (i.e., between 1% and 100%), and by adding neutral density filters (BarnDoor Lighting Outfitters, North Branford, CT, USA) in-between the light source and the 96-well plate. Each neutral density filter blocked approximately 60% of the light. The reduction in light intensity did not alter the color temperature. The following light intensities (log I) were used in the VMR experiments: 0, −0.2, −2.5, −2.9, and −3.3.

During the VMR assay, the larval activity was recorded by Zebralab software (View-Point Life Sciences) running in the quantification mode. The following parameters were used to collect activity data: detection sensitivity per pixel per image—gray level 6; burst threshold—4 pixels; bin size—1 second. The detection sensitivity registered pixels with a gray level below a preset level. These registered pixels detected the individual larvae in each frame. If these pixels were detected in a different location in successive frames, they were declared as active pixels. These active pixels represented the part of the larvae that moved in successive frames. The burst threshold selected movements that were larger than a predefined number of active pixels between successive frames to separate small movements from major movements. In this study, larval movement was summarized as the fraction of frames that a larva displayed movement in each second (as defined by the bin size). This fraction was defined as the Burst Duration and was individually computed for all larvae. All VMR assays were started at approximately the same time at 2 PM in the afternoon to minimize the effect of circadian rhythm on vision. The media were changed every day. The larval genotype was confirmed by PCR after all behavioral experiments. In all experiments, three independent biological replicates were performed. Each biological replicate comprised three technical replicates.

Genotyping

The OKR-negative nof larvae were genotyped after the VMR assay to confirm their homozygosity. Their DNA was extracted by the alkaline lysis method. Briefly, these larvae were heated to 95°C in 50 mM NaOH for 10 minutes in Eppendorf tubes. The solution was vortexed, neutralized with 1M Tris-HCl, and centrifuged at 18,400 g. The supernatant was used in PCR with the following primers: forward—5′-GGAGTTCATCGTGCCAAAAC-3′, reverse—5′-GTGTTTCAACTCACTTCAGCT-3′. The resulting PCR products were digested with PVU-II (New England Biolabs, Ipswich, MA, USA) and run on an agarose gel. The WT PCR product was cut by the enzyme into two bands: a 145 base pairs (bp) band and a 19-bp band, whereas the PCR product with the nof mutation was not cut by the enzyme and remained a 164-bp band.

Statistics

Statistical analysis was performed using R version 3.3.0 . VMR data were processed by DataWorkShop (ViewPoint Life Sciences) to extract locomotor activity after each stimulus change. To compare activity profiles, the locomotor activity from different conditions was segregated into two time periods: 1 to 2 seconds (fast response) and 3 to 10 seconds (sustained response). The activity profiles in these time periods were compared by the Hotelling's T2 test, a statistical approach we developed to analyze VMR data. Finally, the resulting P values were corrected for multiple-hypothesis testing by controlling the false-discovery rate.

Relative Activity

The relative activity between two samples was expressed as a ratio percentage between their areas under the curve (AUC). Two time periods were used in the calculation: 0 to 2 seconds and 2 to 10 seconds. The former period includes the activities used in the statistical analysis of the fast response (the first 2 seconds) as described in the last section, whereas the later period includes the activities used in the statistical analysis of the sustained response (3–10 seconds). In the Results section, the time periods for AUC calculation would be grouped under the fast and sustained responses used in the statistical analysis for clarity.

Results

The nof Mutation Inactivated Cone Function But Not Rod Function

We first confirmed the lack of cone function in the nof mutants by ERG measurements (Fig. 1). The mutant larvae were identified by their lack of an OKR at 5 dpf (OKR–). Their ERGs were measured under photopic condition (5.3 × 104 µW/cm2 at 500 nm; log I = 0) at 6 dpf and compared with those obtained from WT siblings (OKR+). The OKR+ larvae displayed ERGs that consist of three typical components (Fig. 1A): a small initial a-wave during light onset that represents the hyperpolarization of photoreceptors, a depolarizing b-wave that reflects ON-bipolar cell activity, and a depolarizing d-wave during light offset that reflects OFF-bipolar cell activity, driven by cones. The OKR– (nof) larvae, on the contrary, did not display any ERGs under normal photopic conditions (Fig. 1B).

Figure 1.

Photopic ERG of WT and nof mutant larvae at 6 dpf. (A) ERGs of 6-dpf larvae that displayed OKR (WT phenotype; OKR+). (B) ERGs of 6-dpf OKR- (nof) larvae. All samples were adapted to light at 200 µW/cm2 at 500 nm for at least 2 hours before the experiments. The light stimulus was a 500-ms full-field light flash of 5.3 × 104 µW/cm2 at 500 nm (log I = 0). Each trace is an average of six responses. The nof mutants did not display any ERG under photopic conditions.

To measure potential rod function, the ERGs of these larvae after 2-hour dark adaptation were measured over 5 log units of light intensities (Fig. 2). In this preparation, both OKR+ and OKR- larvae displayed ERGs (Fig. 2A). The OKR- ERG was much smaller than the OKR+ ERG at all intensities, except for log I = −5. At this light intensity, the b-wave amplitudes were comparable between OKR- larvae and OKR+ larvae, in both cases approximately 33 µV (Fig. 2B). As the light intensity increased, the b-wave amplitudes of the OKR+ larvae increased substantially, whereas those of the OKR- larvae remained in the range of 30 to 70 µV.

Figure 2.

The nof mutants displayed scotopic ERGs after dark adaptation. (A) ERGs of OKR+ larvae (left panel) and OKR- larvae (right panel) over 5 log units of light attenuation. The unattenuated light stimulus was a 200-ms full-field light flash of 5.3 × 104 µW/cm2 at 500 nm (log I = 0). Each trace is an average of three responses. (B) Bar graph indicating the b-wave amplitude averages of OKR+ (n = 3) and OKR- (n = 3) larvae over 5 log units of light attenuation. After dark adaptation, both OKR+ and OKR- (nof) larvae were responsive at dim light indicative of rod function.

VMRs in WT Larvae and nof Mutants

We then determined the extent to which the VMR was altered by the nof mutation by comparing the VMRs displayed by WT larvae and nof mutants at 6 to 8 dpf. The results from each stage were consistent, and the 6-dpf results are presented here unless otherwise specified. At log I = 0 (3.77 µW/cm2 at 500 nm), the WT larvae displayed a characteristic fast, transient light-On response in the first two seconds (fast response) (Fig. 3A). They also displayed a sustained response, which consisted of a few peaks starting from the third second and which lasted for almost 30 seconds. Compared with the WT larvae, the nof mutants displayed a significantly different light-On VMR (Fig. 3A). It lacked the sharp activity peak of the fast response (P < 0.0001), and responded, but was slightly less active during the sustained response (3–10s, 82%, P < 0.08). Nonetheless, a few activity peaks were still apparent. During light offset, the WT larvae displayed a characteristic fast, transient light-Off VMR in the first 2 seconds (fast response), and a sustained response with multiple peaks that lasted for several minutes before the activity returned to baseline (Fig. 3B). Compared with the WT larvae, the nof mutants also showed a different light-Off VMR (Fig. 3B) that lacked most of the sharp activity peak of the fast response (P < 0.0001), and their sustained response was also significantly reduced (3–10s, 44%, P < 0.0001).

Figure 3.

VMRs of WT larvae, nof, and chokh/rx3 mutants at log I = 0. VMRs recorded from WT larvae (red; N = 108), nof (green; N = 108), and chokh/rx3 mutants (blue; n = 72) at 6 dpf with a light stimulus of log I = 0 (3.77 µW/cm2 at 500 nm). Activity is the fraction of video frames in which a larva displayed movement each second (see Methods). In each plot, the curves show the average activity of the larvae in each condition. The light and dark phases are shown by white and black bars respectively, at the top of the plots. (A) Light-On VMRs. The nof and chokh/rx3 mutants lacked the fast response (<2 s after light onset) that the WT larvae displayed. All larvae displayed a gradual increase in sustained activity (>2 s after light onset), although the sustained amplitudes of both mutants were considerably smaller than that of WT larvae. (B) Light-Off VMRs. The nof mutants displayed a severe reduction in amplitude of the fast response (<2 s after light offset) compared with that of the WT larvae. All larvae displayed a sustained response (>2 s after light offset), with WT larvae the highest and chokh/rx3 mutants the lowest.

The contribution of the EOPs to the VMR at 6 dpf was evaluated by measuring VMRs displayed by the eyeless chokh/rx3 mutants (Figs. 3A, 3B). On light onset, the chokh/rx3 mutants completely lacked the fast response of the first 2 seconds but they gradually increased their activity from 7 seconds onward (Fig. 3A). During this sustained period, a few activity peaks occurred every few seconds. On light offset, the chokh/rx3 mutants barely displayed any light-Off VMR (Fig. 3B), except perhaps for a small fast off-response.

The Light-On VMR of the nof Mutants at Lower Light Intensities Resembles the WT Response

To evaluate a contribution of rods to the VMR, we lowered the intensity of the light stimuli to levels that would only activate rods. In that case, WT larvae and the nof mutants should display similar light-On VMRs. To test this, we systematically subjected WT larvae, nof and chokh/rx3 mutants to lower light intensities and measured their light-On VMRs (Figs. 4A–D).

Figure 4.

The nof mutants displayed a light-On VMR comparable to that of WT larvae at the lowest light intensities (log I = −2.9 and −3.3). The light-On VMRs of WT larvae (red), nof (green), and chokh/rx3 mutants (blue) were measured at 6 dpf with the following light intensities: log I = −0.2 (A), −2.5 (B), −2.9 (C), and −3.3 (D). The experiments were conducted and resulting data plotted as described in Figure 3. The numbers of animals used are as follows: For (A, B), n = 72 for WT larvae and nof mutants, and n = 48 for chokh/rx3 mutants; for (C), n = 108 for WT larvae and nof mutants, and n = 72 for chokh/rx3 mutants; for (D), n = 36 for WT larvae and nof mutants, and n = 24 for chokh/rx3 mutants. As the light intensity was reduced, WT larvae and the nof mutants displayed fast responses (<2 s after light onset) that became more comparable. The arrows in (C, D) indicate WT and nof mutants displayed a similar fast response in the first 2 s. The chokh/rx3 mutants, however, did not display any fast response. All larvae lacked sustained responses (>2 s after light onset) when the stimulus light intensity was lower than log I = −2.5.

At log I = −0.2, the nof mutants did not display any fast response (Fig. 4A). A small fast peak was detected at log I = −2.5 (Fig. 4B), but it was substantially smaller than the WT response (30%; P < 0.0001). However, at log I = −2.9 and −3.3, the nof mutants displayed fast responses similar to WT larvae (72% and 91%, P > 0.05) (Figs. 4C, 4D). However, the chokh/rx3 mutants displayed no fast response when exposed to light intensities lower than log I = 0.2. Indeed, at light intensities below log I = −2.5, there was a suppression of activity of all sustained responses. The same trend persisted at 8 dpf, except for nof mutants that started to display a small fast response at log I = −0.2 (<50% of WT; P < 0.004).

Rods Contribute to the Light-Off VMR in Zebrafish Larvae

The nof mutants displayed a substantially reduced light-Off VMR compared with WT larvae at all lower light intensities (Figs. 5 A–D). They lacked any fast response at log I = −0.2 and −2.5 but did display a small peak of less than 30% of WT amplitude at log I = −2.9 and −3.3 (P < 0.0001), which chokh/rx3 mutants did not display. The nof mutants also displayed some small, sustained responses that were greater than the responses of the chokh/rx3 mutants (<52% of nof mutants) at all light intensities (P < 0.041).

Figure 5.

The nof mutants displayed a reduced light-Off VMR, which was still higher than that of the chokh/rx3 mutants at low-light intensities. The light-Off VMRs of WT larvae (red), nof (green), and chokh/rx3 mutants (blue) were measured at 6 dpf with the following light intensities: log I = −0.2 (A), −2.5 (B), −2.9 (C), and −3.3 (D). The experiments were conducted and resulting data plotted as described in Figure 3. The numbers of animals used are as follows: For (A, B), n = 72 for WT larvae and nof mutants, and n = 48 for chokh/rx3 mutants; for (C), n = 108 for WT larvae and nof mutants, and n = 72 for chokh/rx3 mutants; for (D), n = 36 for WT larvae and nof mutants, and n = 24 for chokh/rx3 mutants. Compared with WT larvae, the nof mutants always showed a reduction in amplitude of the fast response (<2 s after light offset). The sustained responses (>2 s after light offset) were also noticeably less. Nonetheless, the responses from the nof mutants were generally higher than the ones displayed by the chokh/rx3 mutants.

Figure 6.

Dark-adapted nof mutants displayed an OKR at low-light intensities. In this experiment, heterozygous nof parents were crossed. At 5 dpf, the OKRs of the collected larvae were tested under photopic condition to identify WT larvae (OKR+, n = 10) and nof mutants (OKR-, n = 10). At 6 dpf, these larvae were light-adapted at 200 µW/cm2 at 500 nm (A) or dark-adapted (B) for 2 hours and their OKRs tested over 5 log units of attenuated light (log I = 0; 1.1 × 103 µW/cm2 at 500 nm). The bar charts show the average number of smooth pursuits and saccades per minute as a function of light intensity. The error bars show the standard deviations. The nof mutants displayed an OKR comparable with the WT larvae at log I = −3 or less.

Rods Also Contribute to the OKR in Zebrafish Larvae

We measured the OKR of nof mutants and their WT siblings at 6 dpf over 5 log units of light attenuation (At log I = 0, the irradiance was 1.1 × 103 µW/cm2 at 500 nm). When nof mutants were light-adapted (200 µW/cm2 at 500 nm for 2 hours), a few sporadic smooth pursuits and saccades were recorded at lower light-stimulus intensities. Nonetheless, the mutants did not display any consistent and continuous OKR compared with their WT counterparts, which displayed an OKR with the number of smooth pursuits and saccades per minute correlating with the light-stimulus intensity (Fig. 5A; P < 0.05 for all intensities). The nof mutants did display an OKR when they were dark-adapted before the assay (Fig. 5B). When the light intensity was equal to or lower than log I = −3, the nof mutants displayed an OKR indistinguishable from the WT siblings (P > 0.05). At higher light intensities from log I = −2 to 0, the nof mutants displayed fewer smooth pursuits and saccades per minute (P < 0.05).

Discussion

Our ERG measurements unequivocally demonstrated rod responses from the nof mutant. First, light-stimulus intensities at or below log I = −4 (5.3 µW/cm2 for 200 ms or 1.06 µJ/cm2) (Fig. 2) are comparable or less than those that Brockerhoff et al. used and failed to trigger a response from isolated nof cones (a 10-ms flash of 4.41 × 104 photons/µm2, which is equivalent to 148.3 µW/cm2 for 10 ms or 1.48 µJ/cm2). Although some of the isolated nof cones do respond to very bright light through a transducin-independent increase of cytoplasmic Ca2+, the stimulus intensity was far higher (1.3 × 107 photons/µm2/s for 2 s, which is equivalent to 437.2 µW/cm2 for 2 s or 874.3 µJ/cm2) than our scotopic light-stimulus intensities. This high level of light stimulus is comparable to our log I = −1 (Fig. 2). Together, these results indicate that our scotopic light-stimulus intensities (at or below log I = −4) could not have stimulated any Ca2+-dependent response from nof cones, and that the observed nof ERGs at these intensities were initiated by nof rods. The rod response in larvae was, however, relatively small, most likely due to far fewer rods being present in the larval retinas compared with the adult. This small rod response was likely obscured by the dominating cone activity in the WT larvae, explaining why the earlier ERG studies did not detect rod response at these young ages.

Because young zebrafish rods display electrophysiological responses, could they drive visual behaviors? Our study tested this possibility by VMR and OKR behavioral responses. If rods contribute to the VMR, we would expect to see differences between the responses of WT larvae, nof mutants with rod but no normal cone function, and eyeless chokh mutants. Indeed, the nof mutants displayed attenuated light-On and light-Off VMRs compared with WT larvae, but their VMRs were still higher than those displayed by the chokh/rx3 mutants (Fig. 3). We included the eyeless chokh/rx3 mutants in these studies to eliminate the possibility of a confounding response originating from the EOPs. These EOPs do contribute a bit to the VMR, which is apparent when the results are summarized in minutes., Although our results are summarized in seconds, we can still see some delayed responses by the chokh/rx3 mutants from approximately 5 to 30 s in the light-On VMR at log I = 0 and −0.2, and in the light-Off VMR at all intensities (Figs. 3 and 4). Because all types of samples displayed regular activity peaks in the sustained period in light-Off VMR, these activity peaks likely have other extraocular origins.

Rod function was also demonstrated by the comparisons of VMRs at scotopic light intensities. At or below log I = −2.9 (0.0049 µW/cm2), only WT and nof mutants displayed the fast response in the light-On VMR (Fig. 4), whereas no fast responses were detected in the eyeless chokh/rx3 mutants. These results indicate that EOPs were incapable of initiating the light-On VMR below log I = −2.9 and that the fast response of the nof mutants was likely driven by rods. At higher light intensities, WT larvae displayed a larger fast response compared with nof mutants, suggesting that cones mainly generate the WT fast response at these higher light intensities. The sustained response of light-On VMRs in all samples was largely reduced to the baseline level at or below log I = −2.5, suggesting that this component was primarily driven by cones. For light-Off VMR, the nof mutants displayed a small activity peak in the fast response (Figs. 4C, 4D), which was higher than the eyeless chokh/rx3 mutants, but lower than the WT larvae (with rods and cones). This fast response likely represents rod contribution to the light-Off VMR. For the sustained response of the light-Off VMR, the nof mutants always displayed activities lower than the WT larvae and higher than the chokh/rx3 mutants, again indicating rods’ contribution to the sustained activity. Together, our results strongly suggest that rods contribute to both the light-On and light-Off VMR in young larvae at 6 dpf.

Rod function was further demonstrated in the OKR that evaluates larval capability of tracking moving objects. Light-adapted nof mutants displayed little if any OKR, suggesting the light adaptation saturated their rods (Fig. 5A). Dark-adapted nof mutants, however, displayed OKRs across different light intensities (Fig. 5B). In particular, their OKRs were similar to those displayed by their WT siblings when the light intensity was lower than log I = −3 (1.1 µW/cm2). This light intensity is comparable to the scotopic light intensities used for rod ERG measurement (< log I = 4, or 5.3 µW/cm2 for 200 ms). This again indicates that rods were driving nof OKR at these lower light intensities. At higher light intensities, the nof mutants displayed smaller OKR responses, consistent with the notion that the stronger light intensities saturate the rods, diminishing the response.

Conclusions

We have detected rod function and contributions to both the VMR and OKR in zebrafish larvae as early as 6 dpf. This observation has opened up the possibility of testing new drugs for rod degeneration in zebrafish. We can screen compounds that improve the VMR in rod mutants, as the VMR is amenable to high-throughput screening. In addition, we can use the OKR for a more detailed analysis of specific compounds. Because these behavioral assays detect functional output of rods, they can complement fluorescent-based screening, (Zhang L, et al. IOVS 2017;58:ARVO E-Abstract 4539) that detects rod survival. Together, these screening approaches may expedite discovery of new treatments for retinal degenerations that affect rods.