A study of the reactivity of S(VI)–F containing warheads with nucleophilic amino-acid side chains under physiological conditions

Profiling the reactivity and stability of S^VI–F warheads towards nucleophilic amino acids for the development of biochemical probe compounds.

THE FINE STRUCTURE OF THE PIGMENT EPITHELIUM IN THE ALBINO RAT

In this report, particular attention is paid to the inclusion bodies found in the apical cytoplasm of the pigment epithelial cell. These bodies are of variable size and form. The smallest (0.4 µ diameter) consist of a granular matrix enclosed by a single membrane, and are similar to the lysosomes of hepatic cells. Larger inclusion bodies contain areas of lamellated material in addition to granular matrix. The largest particles seen (2 µ diameter) are almost entirely lamellar. These different forms seem closely related, for it is possible to find all transitional stages between the smallest and largest particles. The relationship between the lamellar inclusion bodies and the rod outer segments is discussed.

Behavioral screening for cocaine sensitivity in mutagenized zebrafish

Understanding the molecular basis of addiction could be greatly aided by using forward genetic manipulation to lengthen the list of candidate genes involved in this complex process. Here, we report that zebrafish exhibit cocaine-induced conditioned place preference. In a pilot screen of 18 F(2) generation families of mutagenized fish, we found three with abnormally low responses to cocaine. This behavior was inherited by the F(3) generation in a manner that suggests the abnormalities were because of dominant mutations in single genes. Performance profiles in secondary behavioral screens measuring visual dark-adaptation and learning suggest that the defects were the result of mutations in distinct genes that affect dopaminergic signaling in the retina and brain.

The perplexed and confused mutations affect distinct stages during the transition from proliferating to post-mitotic cells within the zebrafish retina

To identify and study genes essential for vertebrate retinal development, we are screening zebrafish embryos for mutations that disrupt retinal histogenesis. Key steps in retinogenesis include withdrawal from mitosis by multipotent neuroepithelial cells, specification to particular cell types, migration to the appropriate laminar positions, and molecular and morphological differentiation. In this study, we have identified two recessive mutations that affect the transition of proliferating neuroepithelial cells to postmitotic retinal cells. Both the perplexed and confused mutant phenotypes were initially detectable when the first retinal neuroepithelial cells began to leave the cell cycle. At this time, each mutant retina showed increased cell death and a lack of morphological differentiation. Cell death was found to be apoptotic in both perplexed and confused retinas based on TUNEL analysis and activation of caspase-3. TUNEL-phosphoRb-BrdU colocalization studies indicated that the perplexed mutation caused death in cells transitioning from a proliferative to postmitotic state. For the confused mutation, TUNEL-phosphoRb-BrdU analysis revealed that only a subset of postmitotic cells were induced to activate apoptosis. Mosaic analysis demonstrated that within the retina the perplexed mutation functions noncell-autonomously. Furthermore, whole lens or eye cup transplantations indicated that the retinal defect was intrinsic to the retina. Mosaic analysis with confused embryos showed this mutation acts cell-autonomously. From these studies, we conclude that the perplexed and confused genes are essential at distinct stages during the transition from proliferating to postmitotic cells within the zebrafish retina.

The pineal gland in wild-type and two zebrafish mutants with retinal defects

Light and transmission electron microscopy were used to characterize the ultrastructural features of the pineal glands of wild-type and two mutant zebrafish strains that have retinal defects. Particular attention was given to the pineal photoreceptors. Photoreceptors in the pineal gland appear quite similar to retinal cone photoreceptors, having many of the same structural characteristics including outer segment disk membranes often confluent with the plasma membrane, calycal processes surrounding the outer segments, and classic connecting cilia. The pineal photoreceptor terminals differ from photoreceptor terminals in the retina in that they have short synaptic ribbons and make dyad synapses which may or may not be invaginated. Pineal photoreceptors in two zebrafish mutants with abnormal retinal photoreceptors were also studied. Pineal photoreceptors in the niezerka (nie) mutant degenerate, as they do in the retina, indicating that pineal and retinal photoreceptors share at least some genes. However, the synaptic terminals of no optokinetic response c (nrc) pineal photoreceptors are normal, suggesting that this mutation is specific to the retina.

Synapse formation is arrested in retinal photoreceptors of the zebrafish nrc mutant

We describe the effects of a recessive mutation on visual behavior, the electroretinogram (ERG), and photoreceptor structure in zebrafish. At 6 d post-fertilization (dpf), no optokinetic reflex could be elicited in no optokinetic response c (nrc) mutant animals under any test condition. The animals exhibited ERG responses at 5-7 dpf that were markedly abnormal and could be categorized into two groups. The first showed an initial negative a-wave followed by a delayed positive b-wave of small amplitude. Often a second ERG-like response was recorded after the initial b-wave. The second group showed only a large negative a-wave; an initial b-wave was not evident. In most recordings additional oscillatory waves varying in number, amplitude, and time course were observed. Multiple responses at the cessation of long-duration flashes were also observed. Light and electron microscopy revealed that the cone photoreceptor pedicles of nrc fish were highly abnormal. Although the appropriate number of synaptic ribbons formed in these terminals, they "floated" in the terminal, unassociated with postsynaptic processes or arciform densities. The few processes invaginating the nrc pedicles resembled those of horizontal cells. Invaginating bipolar cell processes were rare, but basal contacts were observed on pedicle surfaces. The severity of the mutation did not change between 6 and 8 dpf, showing that there is neither a delay in development nor a degeneration of the terminals; rather, nrc pedicle development appears arrested. Bipolar cell terminals in the inner plexiform layer made normal ribbon synapses; thus, the mutation appears to affect only the outer retina.

Small molecule developmental screens reveal the logic and timing of vertebrate development

Much has been learned about vertebrate development by random mutagenesis followed by phenotypic screening and by targeted gene disruption followed by phenotypic analysis in model organisms. Because the timing of many developmental events is critical, it would be useful to have temporal control over modulation of gene function, a luxury frequently not possible with genetic mutants. Here, we demonstrate that small molecules capable of conditional gene product modulation can be identified through developmental screens in zebrafish. We have identified several small molecules that specifically modulate various aspects of vertebrate ontogeny, including development of the central nervous system, the cardiovascular system, the neural crest, and the ear. Several of the small molecules identified allowed us to dissect the logic of melanocyte and otolith development and to identify critical periods for these events. Small molecules identified in this way offer potential to dissect further these and other developmental processes and to identify novel genes involved in vertebrate development.

Mutations affecting eye morphology in the developing zebrafish (Danio rerio)

The zebrafish (Danio rerio) has received considerable attention as a mainstream model for the molecular and genetic study of vertebrate development. In our laboratory, we have conducted a third-generation screen of chemically mutagenized zebrafish for recessive mutations affecting the visual system. This report describes the visible phenotypes and number of morphological mutants so far observed and presents a more detailed histological analysis of six of these mutations. Through analysis of mutant larvae, it was determined that several of the subtle morphological mutations resulted in degeneration of specific cellular layers of the retina. Other mutations resulted in some degeneration distributed diffusely across the entire retina or concentrated at the retinal margin. A single mutation affecting invagination of the optic cup and lens vesicle formation resulted in a failure to develop an anterior chamber. These results demonstrate the utility of a small-scale, highly focused screen for uncovering novel loci involved in retinal and eye development.

The zebrafish young mutation acts non-cell-autonomously to uncouple differentiation from specification for all retinal cells

Embryos from mutagenized zebrafish were screened for disruptions in retinal lamination to identify factors involved in vertebrate retinal cell specification and differentiation. Two alleles of a recessive mutation, young, were isolated in which final differentiation and normal lamination of retinal cells were blocked. Early aspects of retinogenesis including the specification of cells along the inner optic cup as retinal tissue, polarity of the retinal neuroepithelium, and confinement of cell divisions to the apical pigmented epithelial boarder were normal in young mutants. BrdU incorporation experiments showed that the initiation and pattern of cell cycle withdrawal across the retina was comparable to wild-type siblings; however, this process took longer in the mutant. Analysis of early markers for cell type differentiation revealed that each of the major classes of retinal neurons, as well as non-neural Muller glial cells, are specified in young embryos. However, the retinal cells fail to elaborate morphological specializations, and analysis of late cell-type-specific markers suggests that the retinal cells were inhibited from fully differentiating. Other regions of the nervous system showed no obvious defects in young mutants. Mosaic analysis demonstrated that the young mutation acts non-cell-autonomously within the retina, as final morphological and molecular differentiation was rescued when genetically mutant cells were transplanted into wild-type hosts. Conversely, differentiation was prevented in wild-type cells when placed in young mutant retinas. Mosaic experiments also suggest that young functions at or near the cell surface and is not freely diffusible. We conclude that the young mutation disrupts the post-specification development of all retinal neurons and glia cells.

Effects of dopamine depletion on visual sensitivity of zebrafish

The visual sensitivity of zebrafish in which the retinal dopaminergic interplexiform cells (DA-IPCs) were destroyed by 6-hydroxydopamine was measured behaviorally. During the first 6-8 min of dark adaptation, visual thresholds of DA-IPC-depleted animals were similar to those of control animals. Thereafter, their visual thresholds were elevated so that by 14-18 min of dark adaptation, they were 2-3 log units above those of control animals. In DA-IPC-depleted animals, the electroretinogram was normal in terms of light sensitivity and waveform, but the light threshold for eliciting a ganglion cell discharge was raised by 1.8 log units as compared with control animals. No obvious rod system function was detected in DA-IPC-depleted animals as measured behaviorally. Partial rescue of the behavioral visual sensitivity loss in DA-IPC-depleted animals occurred when dopamine 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-depleted animals is attributable to effects occurring in the inner retina, mainly on rod signals. We also show that dopamine is involved in mediating the effect of the circadian clock on visual sensitivity.

Disruption of the olfactoretinal centrifugal pathway may relate to the visual system defect in night blindness b mutant zebrafish

We describe here a dominant mutation, night blindness b (nbb), which causes an age-related visual system defect in zebrafish. At 4-5 months of age, dark-adapted nbb(+/-) mutants show abnormal visual threshold fluctuations when measured behaviorally. Light sensitizes the animals; thus early dark adaptation of nbb(+/-) fish is normal. After 2 hr of dark adaptation, however, visual thresholds of nbb(+/-) mutants are raised on average 2-3 log units, and rod system function is not detectable. Electroretinograms recorded from nbb(+/-) mutants are normal, but ganglion cell thresholds are raised in prolonged darkness, suggesting an inner retinal defect. The visual defect of nbb(+/-) mutants may be likely caused by an abnormal olfactoretinal centrifugal innervation; in nbb(+/-) mutants, the olfactoretinal centrifugal projection to the retina is disrupted, and the number of retinal dopaminergic interplexiform cells is reduced. A similar visual defect as shown by nbb(+/-) mutants is observed in zebrafish in which the olfactory epithelium and olfactory bulb have been excised. Homozygous nbb fish display an early onset neural degeneration throughout the CNS and die by 7-8 d of age.

A single amino acid in the second transmembrane domain of GABA rho subunits is a determinant of the response kinetics of GABAC receptors

The rho subunits that constitute the gamma-aminobutyric acid (GABA)C receptors of retinal neurons form a unique subclass of ligand-gated chloride channels that give rise to sustained GABA-evoked currents that exhibit slow offset (deactivation) kinetics. We exploited this property to examine the molecular mechanisms that govern the disparate response kinetics and pharmacology of perch GABA rho1B and rho2A subunits expressed in Xenopus oocytes. Using a combination of domain swapping and site-directed mutagenesis, we identified the residues at amino acid position 320 in the second transmembrane domain as an important determinant of the receptor kinetics of GABAC receptors. When the site contains a proline residue, as in wild-type rho1 subunits, the receptor deactivates slowly; when serine occupies the site, as in wild-type rho2 subunits, the time course of deactivation is more rapid. In addition, we found that the same site also altered the pharmacology of GABA rho receptors, e.g., when the serine residue of the rho2A receptor was changed to proline, the response of the mutant receptor to imidazole-4-acetic acid (I4AA) mimicked that of the rho1B receptor. However, despite gross changes in receptor pharmacology, the apparent binding affinity for the drug was not significantly altered. These findings provide further evidence that the second transmembrane domain is involved in the gating mechanism that governs the response properties of the various rho receptor subunits. It is noteworthy that the proline residue in native rho1 subunits and the serine residue of rho2 subunits are well conserved in all species, a good indication that the presence of multiple GABA rho subunits serves to generate GABAC receptors that display the wide range of response kinetics observed on various types of retinal neurons.

Erratum: Temporal and spatial patterns of opsin gene expression in the zebrafish (Danio rerio): corrections with additions

We report here a reexamination of the developmental expression of cone opsins in the zebrafish retina. The red- and blue-sensitive opsins appear at 51 h postfertilization (hpf) whereas ultraviolet (UV) opsin is not seen until after 55 hpf. More cells show red cone opsin expression than blue at 51 and 55 hpf, indicating the sequence of cone opsin expression in zebrafish is first red, then blue, and finally UV. Curiously, morphological development of the cones is in reverse order; UV cones appear quite mature by day 6-7 postfertilization (pf), but morphologically, red cones do not appear adult-like until 15-20 days pf.

Early retinal development in the zebrafish, Danio rerio: light and electron microscopic analyses

The morphological differentiation of the zebrafish retina was analyzed by using light (LM) and transmission electron (TEM) microscopy between the time of initial ganglion cell differentiation (approximately 32 hours postfertilization; hpf) and shortly after the point when the retina appears functional (approximately 74 hpf), i.e., when all major cell types and basic synaptic connections are in place. The results show that the inner retinal neurons, like the photoreceptor and ganglion cells, differentiate first within the ventronasal region, and differentiation subsequently spreads asymmetrically into the nasal and dorsal regions before reaching the ventrotemporal retina. In addition, we show that the attenuation of the optic stalk occurs in parallel with ganglion cell differentiation between 32 and 40 hpf. The first conventional synapses appear within the inner plexiform layer simultaneously with the first photoreceptor outer segment discs at 60 hpf; functional ribbon triads arise within photoreceptor synaptic terminals at 65 hpf; and synaptic ribbons occur within bipolar cell axon terminals at the time larvae exhibit their first visual responses (approximately 70 hpf). Although development is initially more advanced within the ventronasal region between 50 and 60 hpf, development across the retina rapidly equilibrates such that it is relatively comparable within all quadrants of the central retina by 70 hpf. An area within the temporal retina characterized by tightly packed and highly tiered cones emerges with subsequent development. Retinal differentiation in the zebrafish corresponds with that generally described in other vertebrates and can be correlated with the development of visual and electroretinographic responses in the animal.

Molecular and pharmacological properties of GABA-rho subunits from white perch retina

Five gamma-aminobutyric acid (GABA)-rho subunits were cloned from a white perch retinal cDNA library and expressed in Xenopus oocytes. The deduced amino acid sequences indicated that all are highly homologous to the GABA-rho subunits cloned from mammalian retinas; two clones (perch-rho 1A and perch-rho 1B) were in the rho 1 family, two (perch-rho 2A and perch-rho 2B) were in the rho 2 family, and one clone has been tentatively identified as a perch-rho 3 subunit. When expressed in Xenopus oocytes, all but one of the subunits (rho 3) formed functional homooligomeric receptors. However, the receptors expressed by each of the GABA-rho subunits displayed unique response properties that distinguished one from the other. For example, receptors formed by perch-rho 1B subunits were more sensitive to GABA than the receptors formed by other GABA-rho subunits, the dose-response curves for the various receptors revealed different Hill coefficients, and there were differences in the kinetics of the GABA-induced currents. In addition, the GABA-mediated current-voltage curve for rho 2 receptors was approximately linear, whereas the responses from rho 1 receptors showed outward rectification. A further division in the properties of the GABA-rho subunits was revealed in their responses to imidazole-4-acetic acid (I4AA); the drug behaved as an antagonist on A-type rho receptors and a partial agonist on the B-type rho receptors. These results suggest that there is a large diversity of GABAC receptors in the vertebrate retina, probably formed by homooligomeric and heterooligomeric combinations of GABA rho subunits, that exhibit different functional properties.

Zebrafish visual sensitivity is regulated by a circadian clock

We have recently developed a behavioral assay, based on the escape response of fish to a threatening object, to analyze quantitatively the visual sensitivity of zebrafish. During the course of dark adaptation, we measure the threshold light intensity required to evoke an escape response. Under a normal light-dark (LD) cycle, thresholds for both the cone and rod systems are considerably lower in late afternoon hours than in early morning hours. Over a period of 24 h, zebrafish are most sensitive to visual stimuli prior to light off and least sensitive prior to light on. Under conditions of constant illumination, this rhythm of visual sensitivity persists for several days but is gradually lost. In constant light (LL), the rhythm persists 1-2 days; thereafter, visual thresholds at all times of the day converge at a level similar to thresholds measured in late afternoon hours in control animals. In constant darkness (DD). the rhythm persists at least 5 days; thereafter, it dampens to a level about a half-log unit less sensitive to that measured in the late afternoon hours in control animals. These data suggest that visual sensitivity in zebrafish is regulated by an endogenous circadian clock which functions to decrease the visual sensitivity.

Zebrafish retinal mutants

We have initiated a genetic analysis of the zebrafish visual system to identify novel molecules involved in vertebrate retinal function. Zebrafish are highly visual; they have four types of cones as well as rod photoreceptors, making it possible to study both rod and cone-mediated visual responses. To identify visual mutants, optokinetic responses of mutagenized larvae are measured in a three-generation screen for recessive mutations. By measuring visual behavior our genetic screen has been targeted towards identifying mutants that do not have gross morphological abnormalities. The electroretinogram (ERG) of optokinetic-defective mutants is recorded and their retinas are examined histologically to localize defects to the retina. In this report, we summarize our screening results and ERG and histological analyses of the five morphologically normal mutants we have analyzed to date. Additionally, the more detailed characterization of a red-blind mutant that we have isolated is summarized. Our results indicate that mutants with defects in various processes such as photoreceptor synaptic transmission, photoreceptor adaptation and cell-type specific survival and/or function can be identified using this approach.

Transposition of the mariner element from Drosophila mauritiana in zebrafish

With the increased popularity of zebrafish (Danio rerio) for mutagenesis studies, efficient methods for manipulation of its genome are needed. One approach is the use of a transposable element as a vector for gene transfer in this species. We report here the transformation of zebrafish and germ-line transmission of the mariner element from Drosophila mauritiana. The mariner element was selected because its transposition is independent of host-specific factors. One- to two-cell-stage zebrafish embryos were coinjected with a supercoiled plasmid carrying the nonautonomous mariner element peach and mRNA encoding the transposase. Surviving larvae were reared to adulthood, and the transmission of peach to the F1 generation was tested by PCR. Four of the 12 founders, following plasmid injections on 2 different days, transmitted the element to their progeny. Inheritance of the transgene from the F1 to the F2 generation showed a Mendelian pattern. No plasmid sequences were detected by PCR or Southern blot analysis, indicating transposition of peach rather than random integration of the plasmid DNA. These data provide evidence of transformation of a vertebrate with a transposable element and support the host-independent mechanism for transposition of the mariner element. We suggest this system could be used for insertional mutagenesis or for identifying active regions of the genome in the zebrafish.

Comparative morphology of distal neurons in larval and adult zebrafish retinas

Distal retinal cells from larval (7-10 days postfertilization) and adult zebrafish retinas were cultured in 70% L-15 medium for 4-5 d and comparable cell types identified. Four photoreceptor types were observed in adult retinal cultures, whereas only single cones were isolated from larval retinas. Horizontal cells in both larval and adult cultures were distinguished by their large size and stellate morphology and two subtypes, A and B, were recognized. Bipolar cells were readily identified in adult cultures, but rare in larval cultures. Two bipolar cell types, large and small, were distinguished. Measurements of the various cell types are provided.

A dominant form of inherited retinal degeneration caused by a non-photoreceptor cell-specific mutation

We have isolated a dominant mutation, night blindness a (nba), that causes a slow retinal degeneration in zebrafish. Heterozygous nba fish have normal vision through 2-3 months of age but subsequently become night blind. By 9.5 months of age, visual sensitivity of affected fish may be decreased more than two log units, or 100-fold, as measured behaviorally. Electroretinographic (ERG) thresholds of mutant fish are also raised significantly, and the ERG b-wave shows a delayed implicit time. These defects are due primarily to a late-onset photoreceptor cell degeneration involving initially the rods but eventually the cones as well. Homozygous nba fish display an early-onset neuronal degeneration throughout the retina and elsewhere in the central nervous system. As a result, animals develop with small eyes and die by 4-5 days postfertilization (pf). These latter data indicate that the mutation affecting nba fish is not in a photoreceptor cell-specific gene.

A comparison of GABAC and rho subunit receptors from the white perch retina

There is increasing evidence that GABAC receptors are composed of GABA rho subunits. In this study, we compared the properties of native GABAC receptors with those of receptors composed of a GABA rho subunit. A homologue of the GABA rho gene was cloned from a white perch (Roccus americana) retinal cDNA library. The clone (perch-s) has an open reading frame of 1422 nucleotide base pairs and encodes a predicted protein of 473 amino acids. It is highly homologous to GABA rho subunits cloned from human and rat retinas. The receptors (perch-s receptor) expressed by this gene in Xenopus oocytes show properties similar to those of the GABAC receptors present on white perch retinal neurons. GABA induced a sustained response that had a reversal potential of -27.1 +/- 3.6 mV. The EC50 for the response was 1.74 +/- 1.25 microM, a value similar to that reported for GABAC receptors. Pharmacologically, the responses were bicuculline insensitive and not modulated by either diazepam or pentobarbital as is the case for GABAC receptors. There were, however, some distinct differences between native GABAC and perch-s receptors. I4AA acts as a partial agonist on perch-s receptors whereas it is strictly an antagonist on native GABAC receptors. Picrotoxin inhibition is noncompetitive on perch-s receptors, but both competitive and noncompetitive on GABAC receptors. We conclude that GABAC receptors are formed by GABA rho subunits but that native GABAC receptors probably consist of a mixture of GABA rho subunits.

A new form of inherited red-blindness identified in zebrafish

A red-blind zebrafish mutant, partial optokinetic response b (pob), has been isolated by measuring eye movements of larvae in a three-generation screen for recessive mutations affecting the visual system. pob larvae exhibit eye movements in response to rotating black and white stripes illuminated with white light, but they do not move their eyes when the stripes are illuminated with red light. Physiological, immunohistochemical, and in situ hybridization analyses of pob retinas showed a selective loss of red-sensitive cones at 5 days postfertilization (dpf). At 3 dpf, cells expressing red opsin are present, suggesting that red-sensitive cones form initially but then disappear rapidly, whereas other photoreceptors remain. Linkage analysis indicated that the mutation identified in the pob mutant is not at the red opsin locus. Because red opsin is the only known molecule unique to red cones, these data suggest that a novel gene is required for the maintenance or function of red cones.

Retinal patterning in the zebrafish mutant cyclops

Determination of cell fate in the vertebrate retina has been shown to be largely independent of lineage. After cell fates are determined, retinal neurons become organized in a precise laminar pattern. The mechanisms for this patterning could involve morphogens distributed in gradients or, alternatively, direct cell-cell interactions. In the zebrafish mutant cyclops (Cyc(b16)), most embryos have two partial retinas joined in the ventral midline. This presents developing retinal cells near the midline with abnormal cellular environments, whereas laterally the pattern of developing cells is normal. We examined the consequences of this for patterning in the mutant's retina. We found that the retinas are joined in the midline at the apical surfaces of the photoreceptor layers. A laminar pattern emerges in the midline that preserves normal positional relationships between retinal cell types locally but is abnormal with respect to patterning over the entire retina. Lateral to the midline, retinal patterning appears normal. Metabolic labeling experiments showed that late rounds of DNA synthesis precede the emergence of the novel pattern in this midline region. We conclude that these observations in the cyclops mutant are compatible with mechanisms of pattern formation in the retina involving local cell interactions.

Modulation of endogenous dopamine release in the fish retina by light and prolonged darkness

The effect of light stimuli and prolonged darkness on the release of endogenous dopamine was measured in the white perch and hybrid bass retinas. Isolated retinas were superfused and released dopamine was measured using extraction and high-pressure liquid chromatography separation techniques. Potassium-induced release did not depend on the background illumination nor on the period of previous darkness. Steady white light did not affect release, but flickering light of 2 Hz increased release about two-fold. During prolonged darkness, the release of dopamine increased steadily over the test period of 2 h, but only if the experiments were performed at night. During the day such an increase was not observed. The increased release during prolonged darkness at night was turned off by a short period of steady white light. The release patterns obtained from the white perch and the hybrid bass were similar. However, the hybrid bass retina showed much lower levels of dopamine than did the white perch retina.

On bipolar cell responses in the teleost retina are generated by two distinct mechanisms

1. ON Bipolar cells were recorded in slices obtained from hybrid bass retinas. Cells were identified as bipolar cells by position in the slice, by characteristic voltage- and ligand-gated currents, and by filling with the fluorescent dye Lucifer yellow. Cells were recorded with the use of either whole cell or perforated-patch techniques. Standard electrophysiological protocols were used. Drugs were applied by puffing and by local superfusion. 2. Application of exogenous glutamate to ON bipolar cells generated two characteristic responses. One effect of glutamate was to open a conductance with a reversal potential close to the chloride equilibrium potential. The other effect of glutamate was to close a conductance with a reversal potential near 0 mV. These two effects of glutamate on ON bipolar cells match the effects of light described previously with the use of intracellular recordings. Thus the effects of glutamate that we report here appear to underlie the rod and cone inputs to these cells. 3. Many of the ON bipolar cells recorded demonstrated both classes of responses to glutamate. To isolate the two responses, 500 microM glutamate was first applied, and then glutamate in the presence of 5 microM 2-amino-4-phosphonobutyric acid (APB). APB specifically blocks the effects of glutamate on the putative roddriven glutamate receptor (the glutamate-elicited conductance decrease), allowing us to study in isolation the effects of glutamate on the cone component, the glutamate-activated chloride current (IGlu). 4. By isolating IGlu as described above, and taking advantage of the fact that amphotericin-perforated-patch recordings limit the diffusion of chloride ions between the patch pipette and the cell body, we found the physiological reversal potential of IGlu to be -58.9 +/- 7.7 (SD) mV. 5. Both the putative rod- and cone-mediated glutamatergic inputs to these bipolar cells could be activated by driving the photoreceptors with puffs of potassium. The currents recorded with this technique were very similar to those seen with direct application of glutamate.

Retinoic acid alters photoreceptor development in vivo

Application of exogenous retinoic acid (RA) to zebrafish during the initial stages of photoreceptor differentiation results in a precocious development of rod photoreceptors and an inhibition of cone photoreceptor maturation. The acceleration of rod differentiation is observed initially within the ventral retina 3 days after fertilization, following 24 hr of RA application, and within the dorsal retina 4 days after fertilization, following 48 hr of RA application. The differentiation of rods was impeded significantly when the synthesis of endogenous retinoic acid was inhibited by citral prior to the initial stage of rod differentiation. RA-treated embryos labeled for bromodeoxyuridine (BrdU) uptake revealed that RA exerts its effect on a postmitotic cell population within the developing retina. During normal development in zebrafish, rod differentiation is most robust within the ventral retina, a region previously shown to be rich in RA. Our data suggest that the RA signaling pathway is involved in the differentiation and maturation of both the rod and cone photoreceptors within the developing zebrafish retina.

Comparison of topographical patterns of ganglion and photoreceptor cell differentiation in the retina of the zebrafish, Danio rerio

Earlier studies suggested retinal differentiation in the zebrafish commences ventrally rather than centrally as is the case in other vertebrates. Here we describe the topographical spread of cell differentiation for ganglion cells, double cones and rods in the zebrafish retina between 36 and 72 hours postfertilization (hpf), by using immunohistochemical markers in retinal wholemounts. Staining for all three cell types commenced within the ventral retina on the nasal side of the optic nerve and choroid fissure, at 38 hpf for ganglion cells and 50 hpf for double cones and rods. Within 3 to 4 hours, the staining of ganglion cells and double cones spread in a continuous wave-like fashion into the nasal region of the ventral retina. After this time, the staining patterns for ganglion cells and double cones progressed dorsally into the central and temporal retina. Finally, stained somata of ganglion cells were observed within the temporal-ventral region by approximately 48 hpf, more than 8 hours later than the first ganglion cells within the nasal retina. The topographical spread of double cone staining was slightly less orderly. After staining had extended into the nasal retina between 50 and 54 hpf, a small group of stained double cones often appeared at the temporal edge of the choroid fissure by 56 hpf, simultaneously with initial staining observed dorsal and temporal to the optic nerve. The topographical spread of rod staining in the ventral retina was more symmetrical. After rod staining appeared near the nasal edge of the choroid fissure at 50 hpf, rods accumulated within a localized patch nasal to the fissure. Approximately 5 hours after initial rod staining, scattered rod staining appeared on the temporal side of the choroid fissure (approximately 55-57 hpf). Rods increased rapidly within the ventral retina, and a dense symmetrical patch extended out from the choroid fissure into the nasal and temporal regions of the ventral retina by 70 hpf. A scattered pattern of rod staining also occurred within the dorsal retina at this time.

Retinoic acid establishes ventral retinal characteristics

The developing eye is known to be rich in retinoic acid (RA), and perturbations in RA levels during formation of the optic primordia, as well as RA receptor mutations, cause retinal malformations, especially in ventral eye regions. To test the hypothesis that RA plays a role in the establishment of ventral retinal characteristics, we examined several dorsal and ventral ocular markers in RA-treated zebrafish. The optic stalk represents the ventral-most region of the early eye field. During normal development, the optic stalks constrict, decreasing in width and are gradually replaced by the optic nerve. Systemic high RA levels cause an expansion in the optic stalk with an increased cell content and a patent lumen. In addition, the stalks do not constrict and persist into later stages of development indicating an enhancement of early ventral eye characteristics. Expression of the transcription factor pax[b], normally confined to the ventral retina, expands into the dorsal retina following RA treatment, whereas msh[c], normally expressed in the dorsal retinal pole, disappears. Activity of an aldehyde dehydrogenase that normally occupies the dorsal third of the retina is reduced or abolished following high systemic RA. When a localized RA source, an RA-soaked bead, is placed next to the developing eye, a fissure resembling the choroid fissure appears in the eye facing the bead. Taken together, these observations suggest that RA is involved in the determination of the ventral retina.

A behavioral screen for isolating zebrafish mutants with visual system defects

Optokinetic and phototactic behaviors of zebrafish larvae were examined for their usefulness in screening for recessive defects in the visual system. The optokinetic response can be reliably and rapidly detected in 5-day larvae, whereas the phototactic response of larvae is variable and not robust enough to be useful for screening. We therefore measured optokinetic responses of mutagenized larvae as a genetic screen for visual system defects. Third-generation larvae, representing 266 mutagenized genomes, were examined for abnormal optokinetic responses. Eighteen optokinetic-defective mutants were identified and two mutants that did not show obvious morphological defects, no optokinetic response a (noa) and partial optokinetic response a (poa), were studied further. We recorded the electroretinogram (ERG) to determine whether these two mutations affect the retina. The b-wave of noa larvae was grossly abnormal, being delayed in onset and significantly reduced in amplitude. In contrast, the ERG waveform of poa larvae was normal, although the b-wave was reduced in amplitude in bright light. Histologically, the retinas of noa and poa larvae appeared normal. We conclude that noa larvae have a functional defect in the outer retina, whereas the outer retina of poa larvae is likely to be normal.

GABAA and GABAC receptors on hybrid bass retinal bipolar cells

1. gamma-Aminobutyric acid (GABA) responses from solitory hybrid bass retinal bipolar cells were studied with the use of conventional and perforated whole cell patch-clamp recording. 2. GABA elicited a chloride current in bipolar cells that had both transient and sustained components. The transient component was sensitive to bicuculline and resembled GABAA-mediated currents, whereas the more sustained component was resistant to bicuculline and resembled the responses mediated by GABAC receptors. 3. The bicuculline-resistant GABA responses recorded from the bipolar cells could not be modulated by either diazepam or pentobarbital sodium, and they were unaffected by phaclofen and 2-hydroxysaclofen, GABAB receptor antagonists. On the other hand, the bicuculline-resistant GABA responses could be blocked substantially by imidazole-4-acetic acid (I4AA), a competitive antagonist of GABAC receptors. 4. Noise analysis of the GABA-elicited currents suggested a different single channel conductance for GABAA (10.1 pS) and GABAC receptors (3.6 pS). 5. Zinc, a putative modulator of synaptic transmission, strongly inhibited the GABAC responses on bipolar cells, whereas the GABAA responses were not significantly affected by zinc. 6. The proportion of the GABAC to GABAA responses varied widely between bipolar cells. Local application of GABA onto dendrites or axon terminals showed that both types of GABA receptors are present on both regions of the cell. 7. The distinct properties of these two GABA receptor types suggest that they play different roles in retinal function.

Temporal and spatial patterns of opsin gene expression in zebrafish (Danio rerio)

In zebrafish, the first class of cone photoreceptor to become morphologically distinct is the ultraviolet-sensitive short single cone, at 4 days postfertilization, whereas the last class, the red- and green-sensitive double cone, becomes distinct at 10 days postfertilization. We have examined the time course of visual pigment gene expression in zebrafish using whole-mount in situ hybridization. Within the retina, opsins may be detected as early as 40 h postfertilization with the ultraviolet and rod visual pigments being expressed before the blue- (48 h) and red- (60 h) sensitive pigments. In the pineal, red-sensitive opsin is expressed at 48 h postfertilization. Visual pigment expression provides a useful tool for investigations of early cell fate in zebrafish.

Dark-suppression and light-sensitization of horizontal cell responses in the hybrid bass retina

The responsiveness of luminosity-type horizontal cells, recorded intracellularly from isolated hybrid bass retinas, decreased after superfusion for 2 h in constant darkness. Responsiveness was subsequently increased (light-sensitized) up to 10-fold after exposure to several short (approximately 0.5 min) periods of continuous illumination. The increase in horizontal cell responsiveness following light-sensitization was due to an increase of peak response amplitude rather than a reduction of peak response time. The increased responsiveness after light-sensitization was intensity-dependent with brighter sensitizing stimuli causing a greater increase than dimmer stimuli. The extent of LHC dark-suppression was affected by the time of day, being greater when induced during the night than during the day. However, there was no significant difference in horizontal cell responsiveness after light-sensitization in retinas studied during the night compared to those studied during the day. The responsiveness of light-sensitized horizontal cells from isolated hybrid bass retinas was found to be suppressed by relatively brief periods of darkness. The responsiveness of horizontal cells, that were first light-sensitized, decreased by more than 50% following only 5 min of darkness. Suppression of light-sensitized horizontal cell responsiveness after such a short time in the dark has not been described in other teleost retinas. The suppression of light-sensitized horizontal cell responsiveness in hybrid bass retinas may be rapid in comparison to other teleosts.

A glutamate-activated chloride current in cone-driven ON bipolar cells of the white perch retina

Cone-driven ON-type bipolar cells were patch clamped in white perch retinal slices. Application of glutamate activated a current (IGlu) that was mediated by a conductance increase. The reversal potential for IGlu followed ECl closely when the intracellular chloride concentration was varied. IGlu was not blocked by 100 microM picrotoxin or 1 microM strychnine, indicating that it was not caused by inhibitory input. IGlu is not mediated by a typical ionotropic glutamate receptor since it was not activated by kainate, AMPA, or NMDA, or blocked by kynurenic acid, CNQX, DNQX, or AP-V. Further, IGlu is not mediated by a known metabotropic glutamate receptor since it was not activated by quisqualic acid, AP-4, ACPD, or ibotenate. IGlu required the presence of extracellular sodium and could be partially inhibited by the glutamate uptake inhibitors THA and tPDC. This is suggestive of sodium-dependent glutamate transport. However, when intracellular sodium was greatly increased, neither the magnitude nor reversal potential of IGlu was substantively affected. Thus, IGlu appears to involve a chloride channel activated by a glutamate receptor with transporter-like pharmacology. IGlu is localized to the dendrites of the bipolar cell, where bipolar cells receive an endogenous glutamatergic input from photoreceptors. Further, the reversal potential of the light response in these cells is the same as that of IGlu. Thus, it seems likely that IGlu is the current responsible for the cone component of the ON bipolar cell light response in the teleost retina.

Threshold and chromatic sensitivity changes in fish cone horizontal cells following prolonged darkness

The light-evoked responses of L-type cone horizontal cells in the teleost retina were studied following a prolonged period of complete darkness. Intact, isolated white perch retinas were superfused in complete darkness for more than 90 min, following which horizontal cells were impaled without the aid of any light flashes. Following this prolonged darkness, L-type cone horizontal cell light responses to dim and bright full-field stimuli were slow and small in amplitude and response duration to bright stimuli was considerably longer than stimulus duration. In addition, absolute threshold was 2 log units lower than typical for cone horizontal cells and spectral sensitivity to shorter wavelengths was increased. Following bright light stimulation, light responses became more transient and increased in amplitude, reaching 40-50 mV to bright flashes. Moreover, absolute threshold increased and responses to spectral stimuli were similar to those observed typically for L-type cone horizontal cells after light-sensitization. These results suggest that following prolonged darkness, cone input to cone horizontal cells is reduced and rod input is present.

Protein content and cAMP-dependent phosphorylation of fractionated white perch retina

In the retinas of teleost fish dopamine, released from interplexiform cells, modulates synaptic transmission at both the chemical and electrical synapses of retinal horizontal cells. This modulation is due to activation of adenylate cyclase and phosphorylation by protein kinase A, perhaps of the synaptic ion channel proteins themselves. In this study we have fractionated the white perch retina by Percoll density gradient centrifugation in order to identify proteins which coenrich with horizontal cells. In addition we have tested retinal fractions for phosphorylation by native cAMP-dependent kinase. Our findings indicate that there are at least 3 proteins of molecular weights 28, 43/44 and 50 kDa which coenrich with horizontal cells and 3 proteins of 30/31 kDa, 35 kDa (putative rhodopsin) and 48 kDa (putative arrestin) which coenrich with photoreceptor fractions. The 43/44 kDa phosphoprotein is a target for cAMP-dependent protein phosphorylation and thus is apparently an element of the dopaminergic modulatory pathway in perch horizontal cells.

Retinoic acid is necessary for development of the ventral retina in zebrafish

In the embryonic zebrafish retina, as in other vertebrates, retinoic acid is synthesized from retinaldehyde by two different dehydrogenases, one localized dorsally, the other primarily ventrally. Early in eye development only the ventral enzyme is present. Citral competitively inhibits the ventral enzyme in vitro and decreases the production of retinoic acid in the ventral retina in vivo. Treatment of neurula-stage zebrafish embryos with citral during the formation of the eye primordia results in eyes lacking a ventral retina. This defect can be partially rescued by retinoic acid. The results demonstrate that synthesis of retinoic acid can be selectively inhibited in vivo and suggest that retinoic acid is necessary for the proper development of the ventral retina.

Pharmacology of novel GABA receptors found on rod horizontal cells of the white perch retina

A novel type of GABA receptor is present on rod-driven (H4) horizontal cells of the white perch retina (Qian and Dowling, 1993a). These receptors have been tentatively termed GA-BAC receptors. In this study, the pharmacological properties of these receptors were further investigated by applying several conformationally restricted GABAA receptor agonists, GABAA antagonists, and a GABAB agonist to the H4 horizontal cells. GABA analogs locked in a partially folded conformation had a variety of effects. Isonipecotic acid had no effect on these receptors, whereas isoguvacine activated them but with low potency (EC50 = 137 microM). THIP (4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol) acted as a competitive antagonist on these receptors with an inhibition constant of 82.5 microM. P4S (piperidine-4-sulfonic acid) activated the receptors at high concentrations (> 1 mM), but at lower concentrations it was a competitive antagonist with an inhibition constant of 80.9 microM. 14AA (imidazole-4-acetic acid), a GABA analog with an extended conformation, potently inhibited the GABA responses on H4 horizontal cells with an inhibition constant of 1.67 microM. Muscimol, which can assume both partially folded and extended conformations, acted as a mixed agonist-antagonist. The GABA responses on H4 horizontal cells were resistant to several competitive GABAA receptor antagonists including bicuculline, hydrastine, and SR-95531, but they were very sensitive to picrotoxin (IC50 = 237 nM). The inhibition by picrotoxin was both competitive and noncompetitive in nature. On the other hand, TBPS (tert-butyl-bicyclophosphorothionate), another GABAA receptor channel blocker, had minimal effects on these receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Early eye morphogenesis in the zebrafish, Brachydanio rerio

Early eye morphogenesis in the zebrafish between 12 and 36 hours postfertilization was studied by light- and scanning electron microscopy. Overall, early eye morphogenesis in the zebrafish is similar to that of other vertebrates even though the optic primordia evaginate from the forebrain as solid masses of cells. After initial evagination (6-7 somite stage [SS]), the optic primordia take on a wing-like shape (8-9 SS). Subsequently, they bend ventrally and rotate slightly in an anterior direction (10-12 SS). These changes serve to bring the primordia from a horizontal to a more vertical orientation in relation to the embryonic neural axis. Invagination commences from the center of each primordium (14 SS) and progresses symmetrically out towards the periphery (14-20 SS). The choroid fissure forms by an involution along the anterior region of the eyecup (18-20 SS). By 24 hours postfertilization (pf), the eyecups are well formed. Between 24 and 36 hours pf, the eyes rotate further in relation to the axis of the embryo, and this repositions the choroid fissue to a typical ventral location by 36 hours pf. Because of the two rotations of the eye during early morphogenesis, particularly the later one, the anterior-posterior orientation of the emerging optic primordium ultimately becomes the ventral-dorsal axis of the completed eyecup.

The excitatory and inhibitory amino acid receptors on horizontal cells isolated from the white perch retina

1. The distribution and the properties of receptors to the inhibitory amino acid glycine (GLY) and the excitatory amino acid glutamate (GLU) and its analogues kainate (KA), quisqualate (QUIS), alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), and N-methyl-D-aspartate (NMDA), were studied with whole-cell and outside-out patch-clamp techniques on all four types of horizontal cells isolated from the retina of white perch. 2. Glycine at concentrations above 30 microM evoked whole-cell current responses from two types of horizontal cells (H2 and H4). The other two types of horizontal cells (H1 and H3) were unresponsive to GLY (30 microM-3 mM). 3. Responses elicited by GLY from H2 and H4 cells were similar, consisting of inward currents that desensitized with a half-decay time of 0.5-2 s at glycine concentrations between 100 and 500 microM. GLY-activated currents were inhibited by the glycine receptor antagonist strychnine (STRYCH). Current responses evoked by GLY reversed at the Cl- equilibrium potential. 4. Dose-response analysis of peak currents induced by GLY revealed a Hill coefficient of 2.0 +/- 0.1 (mean +/- SD, n = 3) and an median effective concentration (EC50) of 85 +/- 2 microM (n = 3). 5. Single glycine receptor channels recorded from outside-out patches had a main-state conductance of 47 +/- 4 pS (n = 3). 6. Every type of horizontal cell from the white perch responded to GLU, KA, QUIS, and AMPA but none responded to exogenously applied NMDA (200 microM) or NMDA (200 microM) + GLY (1 microM) in a Mg+2-free bathing solution. 7. The ratio of the amplitude of responses to GLU, KA, QUIS, and AMPA remained nearly constant among all the horizontal cells tested, suggesting there might be only a single population of non-NMDA receptors on these cells. 8. QUIS and KA both elicited responses from the horizontal cells. When applied together with KA, QUIS competitively antagonized the responses of horizontal cells to KA. 9. The results demonstrated the existence of an inhomogeneous distribution of strychnine-sensitive glycine receptors and a homogeneous distribution of non-NMDA type glutamate receptors among the four types of white perch horizontal cells.

Zebrafish ultraviolet visual pigment: absorption spectrum, sequence, and localization

In many vertebrates, UV-sensitive photoreceptors have been identified by microspectrophotometry and UV-visual sensitivity has been identified by behavioral studies, but as yet no vertebrate UV-sensitive pigment gene has been isolated. We have sequenced a cDNA clone that hybridizes to short single cone cells in the zebrafish (Brachydanio rerio). These cells, which make up 25% of the cone population in zebrafish retinae, are UV-sensitive (lambda max approximately 360 nm). The visual pigment encoded by this gene is unusual in that its amino acid sequence is more homologous to the rod pigment rhodopsin (up to 89%) than to other cone pigments (35-83%). Like all other vertebrate visual pigments, it contains a lysine residue at position 296, the presumptive retinal binding site, and a glutamate residue at position 113. However, it is unique in possessing a lysine residue at position 126, which may account for the UV-sensitivity of the pigment.