Research Article
D2-like dopamine receptors promote interactions between calcium and chloride channels that diminish rod synaptic transfer in the salamander retina
- WALLACE B. THORESON, SALVATORE L. STELLA, ERIC J. BRYSON, JOHN CLEMENTS, PAUL WITKOVSKY
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- 05 September 2002, pp. 235-247
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Activation of D2-like dopamine receptors in rods with quinpirole stimulates L-type calcium currents (ICa). This result appears inconsistent with studies showing that D2-like dopamine receptor activation diminishes rod signals in second-order retinal neurons. Since small reductions in [Cl−]i can inhibit photoreceptor ICa, we tested the hypothesis that enhancement of ICa with the D2/D4 receptor agonist, quinpirole, increases calcium-activated chloride currents (ICl(Ca)) causing an efflux of Cl− from rods that would provide a negative feedback inhibition of ICa. In agreement with studies from Xenopus, quinpirole reduced rod input to second-order neurons of tiger salamander retina without significantly altering rod voltage responses. Quinpirole also diminished the amplitude of depolarization-evoked increases in [Ca2+]i measured with Fura-2 in rods, a finding consistent with inhibition of synaptic transmission from rods. Electrophysiological and Cl−-imaging experiments indicated ECl in rods is ∼ −20 mV. Quinpirole enhanced ICl(Ca) and elicited an efflux of Cl− at the resting potential. A similar Cl− efflux was produced by extracellular replacement of 24 mM Cl− with CH3SO4− and this low Cl− solution inhibited Ca2+responses to a similar degree as quinpirole did. When ICl(Ca) was inhibited with niflumic acid, quinpirole enhanced both ICa and depolarization-evoked increases in [Ca2+]i. Furthermore, with niflumic acid, quinpirole no longer inhibited rod inputs into horizontal and bipolar cells. These results suggest an initial enhancement of ICa by quinpirole is followed by a stimulation of Cl− currents, including ICl(Ca). The net result is a Cl− efflux that inhibits depolarization-evoked increases in [Ca2+]i and synaptic transmission from rods.
NMDA-evoked [Ca2+]i increase in salamander retinal ganglion cells: Modulation by PKA and adrenergic receptors
- YI HAN, SAMUEL M. WU
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- 05 September 2002, pp. 249-256
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Application of NMDA induces a depolarization and increase of intracellular calcium concentration ([Ca2+]i) in retinal ganglion cells, which cause ganglion cell death in models of glaucoma. In the present study, we investigated the pharmacological mechanism of how NMDA-evoked increase in calcium could be modulated in dissociated retinal ganglion cells from tiger salamander. In these neurons, protein kinase A (PKA) up-regulated the NMDA-evoked [Ca2+]i increase. In the presence of 8-bromo-cAMP or forskolin to stimulate PKA, the elevation level of [Ca2+]i induced by NMDA became even higher; In the presence of H-89, a PKA inhibitor, the NMDA-evoked [Ca2+]i increase was attenuated. In addition, applications of adrenergic compounds were also found to influence the NMDA-evoked [Ca2+]i increase. UK-14,304, a selective α2 agonist, reduced the elevation level of [Ca2+]i caused by NMDA. In contrast, isoproterenol, a β agonist, augmented the NMDA-evoked [Ca2+]i increase. These adrenergic regulations were due to direct activation of adrenoceptors, since modulations of both UK-14,304 and isoproterenol on the NMDA-evoked [Ca2+]i increase were abolished by their respective antagonists. Furthermore, adrenergic regulations were mediated through a PKA-related pathway since PKA inhibitor blocked adrenergic regulations. The possible modulatory site(s) by PKA was also discussed.
Transgenic expression of a GFP-rhodopsin COOH-terminal fusion protein in zebrafish rod photoreceptors
- BRIAN D. PERKINS, PAMELA M. KAINZ, DONALD M. O'MALLEY, JOHN E. DOWLING
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- 05 September 2002, pp. 257-264
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To facilitate the identification and characterization of mutations affecting the retina and photoreceptors in the zebrafish, a transgene expressing green fluorescent protein (GFP) fused to the C-terminal 44 amino acids of Xenopus rhodopsin (Tam et al., 2000) under the control of the 1.3-kb proximal Xenopus opsin promoter was inserted into the zebrafish genome. GFP expression was easily observed in a ventral patch of retinal cells at 4 days postfertilization (dpf). Between 45–50% of the progeny from the F1, F2, and F3 generations expressed the transgene, consistent with a single integration event following microinjection. Immunohistochemical analysis demonstrated that GFP is expressed exclusively in rod photoreceptors and not in the UV, blue, or red/green double cones. Furthermore, GFP is localized to the rod outer segments with little to no fluorescence in the rod inner segments, rod cell bodies, or rod synapse regions, indicating proper targeting and transport of the GFP fusion protein. Application of exogenous retinoic acid (RA) increased the number of GFP-expressing cells throughout the retina, and possibly the level of expressed rhodopsin. When bred to a zebrafish rod degeneration mutant, fewer GFP-expressing rods were seen in living mutants as compared to wild-type siblings. This transgenic line will facilitate the search for recessive and dominant mutations affecting rod photoreceptor development and survival as well as proper rhodopsin expression, targeting, and transport.
Melatonin receptor mRNA localization and rhythmicity in the retina of the domestic chick, Gallus domesticus
- ARJUN K. NATESAN, VINCENT M. CASSONE
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- 05 September 2002, pp. 265-274
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The indoleamine hormone melatonin is synthesized and released by photoreceptors during the night within the chick retina, and confers timing information to modulate retinal physiology. Three subtypes of melatonin receptor with nearly identical pharmacological profiles have been described in chickens and are present in the retina. In this study, the spatial localization and temporal pattern of the mRNA for each of these receptors within the retina are described. The localization and rhythmicity of receptor mRNA were analyzed using in situ hybridization and RNase protection assay, respectively, with probes against specific nucleotide sequences encoding these receptors. Mel1A and Mel1C receptor mRNA have similar patterns of expression, primarily in the inner segments of photoreceptors, vitread portion of the inner nuclear layer, and in the retinal ganglion cell layer. Mel1B receptor mRNA is expressed at higher levels in the retina, with expression in photoreceptors, throughout the inner nuclear layer, and in the ganglion cell layer. Mel1A receptor mRNA is rhythmic in both light:dark (LD) cycles and in constant darkness (DD); Mel1A peaks during midday and mid-subjective day, respectively. Mel1C receptor mRNA is also rhythmically expressed in LD, but with a lower amplitude, such that transcript is high during the day and low during the night. In DD, Mel1C rhythms become 180 deg out of phase with a slight increase at night. Mel1B mRNA expression was highly variable and arrhythmic.
Activation of group II metabotropic glutamate receptors inhibits glutamate release from salamander retinal photoreceptors
- MATTHEW H. HIGGS, PETER D. LUKASIEWICZ
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- 05 September 2002, pp. 275-281
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We investigated the effects of group II metabotropic glutamate receptor (mGluR) activation on excitatory synaptic transmission in the salamander retinal slice preparation. The group II selective agonists DCG-IV and LY354740 reduced light-evoked excitatory postsynaptic currents (EPSCs) in ganglion cells. To determine the synaptic basis of this effect, we also recorded from bipolar cells and horizontal cells. In ON bipolar cells, DCG-IV increased the inward current in darkness but did not affect the peak current at light onset. In OFF bipolar cells and horizontal cells, DCG-IV had the opposite effect, reducing the inward current in darkness. Given the opposite polarities of these two classes of synapses, our results suggest that group II mGluRs act presynaptically to reduce glutamate release from photoreceptors. To determine whether DCG-IV affected rods or cones, we applied light stimuli that selectively activate each type of photoreceptor. In horizontal cells, most of which receive mixed synaptic input from rods and cones, DCG-IV reduced rod-driven EPSCs evoked by 470-nm stimuli and cone-driven EPSCs elicited by 700-nm stimuli in the presence of a rod-saturating background. Thus, activation of group II mGluRs reduced rod- and cone-mediated glutamate release. Our results suggest that group II mGluRs could mediate feedback by which extracellular glutamate inhibits glutamate release from photoreceptor terminals.
Central regulation of photosensitive membrane turnover in the lateral eye of Limulus. I. Octopamine primes the retina for daily transient rhabdom shedding
- RASHMI V. KHADILKAR, JOHN R. MYTINGER, LAURA E. THOMASON, SCOTT L. RUNYON, KEVIN J. WASHICOSKY, ROBERT N. JINKS
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- 05 September 2002, pp. 283-297
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Limulus lateral eyes shed and renew a portion of their photosensitive membrane (rhabdom) daily. Shedding, in many species including Limulus, is regulated by complex interactions between circadian rhythms and light. Little is known about how circadian clocks and photoreceptors communicate to regulate shedding. Limulus photoreceptors do not contain an endogenous circadian oscillator, but rely upon efferent outflow from a central clock for circadian timing. To investigate whether the putative efferent neurotransmitter octopamine (OA) communicates circadian rhythms that prime the lateral eye for transient rhabdom shedding, we decoupled photoreceptors from the clock by transecting the lateral optic nerve (contains the retinal efferent fibers). Overnight (6 h) intraretinal injections of 40 μM OA restored transient shedding to lateral eyes with transected nerves to levels comparable to those of intact internal control eyes. To determine whether OA acts alone in communicating circadian rhythms that prime the lateral eye for transient shedding, we “primed” eyes with intact nerves for transient shedding with exogenous OA during subjective day. In nature, lateral eyes shed their rhabdoms only once a day at dawn following overnight efferent priming. Eyes in animals placed in darkness during subjective day, when the retinal efferents are quiescent, and injected for 6 h with 40 μM OA shed their rhabdoms in response to a second introduction to light. Untreated control eyes of the same animals did not. The same results were observed in vitro in lateral eyes treated similarly. Octopamine is the only efferent neurotransmitter/messenger required to make lateral eyes competent for transient shedding. Phentolamine, an OA receptor antagonist, reduced the number of photoreceptors primed for transient shedding and the amount of rhabdom shed in those photoreceptors suggesting that OA acts via a specific OA receptor.
Synaptic input to an ON parasol ganglion cell in the macaque retina: A serial section analysis
- DAVID W. MARSHAK, ELIZABETH S. YAMADA, ANDREA S. BORDT, WENDY C. PERRYMAN
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- 05 September 2002, pp. 299-305
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A labeled ON parasol ganglion cell from a macaque retina was analyzed in serial, ultrathin sections. It received 13% of its input from diffuse bipolar cells. These directed a large proportion of their output to amacrine cells but received a relatively small proportion of their amacrine cell input via feedback synapses. In these respects, they were similar to the DB3 bipolar cells that make synapses onto OFF parasol cells. Bipolar cell axons that contacted the ON parasol cell in stratum 4 of the inner plexiform layer always made synapses onto the dendrite, and therefore, the number of bipolar cell synapses onto these ganglion cells could be estimated reliably by light microscopy in the future. Amacrine cells provided the majority of inputs to the ON parasol cell. Only a few of the presynaptic amacrine cell processes received inputs from the same bipolar cells as the parasol cells, and most of the presynaptic amacrine cell processes did not receive any inputs at all within the series. These findings suggest that most of the inhibitory input to the ON parasol cell originates from other areas of the retina. Amacrine cells presynaptic to the parasol ganglion cell interacted very infrequently with other neurons in the circuit, and therefore, they would be expected to act independently, for the most part.
Does the neurotransmitter transporter underlie adaptation at a histaminergic photoreceptor synapse?
- ANN E. STUART, KELLEY A. GEBHARDT, STACY N. VOGEL, OLGA RODRIGUEZ
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- 05 September 2002, pp. 307-319
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Using autoradiographic and biochemical techniques, we studied the sodium-dependent forward and reverse transport of the neurotransmitter histamine in an arthropod photoreceptor in order to test whether the transporter plays a central role in visual signal transfer at this synapse. In particular, we asked whether the histamine transporter might be the important factor in synaptic adaptation, the process by which the operating range of the synapse adapts to increasing depolarizations of the photoreceptor in increasing background light. Drugs known from electrophysiological observations to interfere with synaptic adaptation blocked the uptake of [3H]histamine into photoreceptors. These drugs also blocked the sodium (Na)-triggered efflux of [3H]histamine, previously loaded into photoreceptors, via the histamine transporter. Several lines of evidence showed that efflux of [3H]histamine did not occur via calcium-dependent exocytosis. First, efflux occurred when the preparation was bathed in calcium (Ca)-free/EGTA salines or in cobalt (Co)-containing salines. Even more importantly, efflux could be elicited from axons, whose membranes must contain the transporter protein since they take up [3H]histamine independently from the presynaptic terminals. Since both adaptation and the histamine transporter are blocked by the same agents, the transporter may underlie adaptation by maintaining the cleft histamine concentration in a particular range independent of light intensity. We also characterized the transporter further and found that it is partially dependent on chloride ions, and that neither [3H]norepinephrine nor [3H]dopamine are transported (at 20 μM), adding to evidence that the transporter is highly selective for histamine.
Distribution and origin of the catecholaminergic innervation in the amphibian mesencephalic tectum
- CRISTINA SÁNCHEZ-CAMACHO, OSCAR MARÍN, AGUSTÍN GONZÁLEZ
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- 05 September 2002, pp. 321-333
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The mesencephalic tectum plays a prominent role in integrating both visual and multimodal sensory information essential for normal behavior in amphibians. Activity in the mesencephalic tectum is thought to be modulated by the influence of distinct neurochemical inputs, including the catecholaminergic and the cholinergic systems. In the present study, we have investigated the distribution and the origin of the catecholaminergic innervation of the mesencephalic tectum in two amphibian species, the anuran Rana perezi and the urodele Pleurodeles waltl. Immunohistochemistry for dopamine and two enzymes required for the synthesis of catecholamines, tyrosine hydroxylase (TH) and dopamine β-hydroxylase (DBH), revealed a complex pattern of catecholaminergic (CA) innervation in the anuran and urodele mesencephalic tectum. Dopaminergic fibers were primarily present in deep tectal layers, whereas noradrenergic (DBH immunoreactive) fibers predominated in superficial layers. Catecholaminergic cell bodies were never observed within the tectum. To determine the origin of this innervation, applications of retrograde tracers into the optic tectum were combined with immunohistochemistry for TH. Results from these experiments demonstrate that dopaminergic neurons in the suprachiasmatic and juxtacommissural nuclei (in Rana) or in the nucleus pretectalis (in Pleurodeles), together with noradrenergic cells of the locus coeruleus, are the sources of CA input to the amphibian mesencephalic tectum. The present results suggest that similar CA modulatory inputs are present in the mesecencephalic tectum of both anurans and urodeles.
Effects of surround motion on receptive-field gain and structure in area 17 of the cat
- LARRY.A. PALMER, JOHN.S. NAFZIGER
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- 05 September 2002, pp. 335-353
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Modulation of responses elicited by moving bars within the classical receptive fields (CRF) of cat area 17 neurons were studied as a function of the direction and velocity of drifting gratings in the surrounds. Several different types of modulation were observed; collectively, the responses of most cells, both simple and complex, were strongly modulated by surround motion. None of these cells appear to signal relative velocity between the CRF and its surround. The gain and spatiotemporal structure of the CRF mechanism were estimated using contrast-response functions and reverse correlation with spatiotemporal ternary white noise, respectively. These measurements were made in the presence of surround gratings shown to significantly modify responses elicited from the CRF. In all cases, the gain of the CRF mechanism was driven up or down relative to controls but the receptive-field structure did not change in any way. We conclude that neurons in cat area 17 act like scalable filters, meaning that their gains can be adjusted by stimuli in the surrounds without altering the properties of the CRF. This was verified by showing that velocity tuning curves were also unmodified by stimuli in the surround that did change the gain. Based in part on these data, we discuss the notion that primary visual cortex makes use of a double-opponent mechanism for the representation of local discontinuities in motion and orientation.
Activation of Group III mGluRs increases the activity of neurons in area 17 of the cat
- C.J. BEAVER, Q-H. JI, X-T. JIN, N.W. DAW
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- 05 September 2002, pp. 355-364
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Activation of Group III metabotropic glutamate receptors (mGluRs) by L(+)-2-amino-4-phosphonobutyric acid (L-AP4) has different effects on in vitro slice preparations of visual cortex (Jin & Daw, 1998) as compared with in vivo recordings from somatosensory cortex (Wan & Cahusac, 1995). To investigate the role of Group III mGluRs in the cat visual cortex, in vivo recordings were made of neurons in area 17 of the visual cortex of kittens and adult cats at different ages and the effect of iontophoretic application of L-AP4 (100 mM) was examined. Application of L-AP4 resulted in an increase of the spontaneous activity and visual response of neurons to visual stimulation, the former more than the latter. The effect of L-AP4 was greatest at 3–5 weeks of age with the effect on the visual response declining more rapidly than the effect on spontaneous activity. Consistent with work in rat cortex (Jin & Daw, 1998), the effect of L-AP4 was significantly greater in upper and lower layers than in middle layers. Whole-cell in vitro recordings from slices of rat visual cortex indicated that L-AP4 (50 mM) did not increase the number of spikes elicited by increasing levels of current injections. These results confirm that L-AP4 increases activity in vivo and reasons for the discrepancy with the in vitro results are discussed.
Mapping absorbance spectra, cone fractions, and neuronal mechanisms to photopic spectral sensitivity in the zebrafish
- DAVID A. CAMERON
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- 05 September 2002, pp. 365-372
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The four spectral cone types in the zebrafish retina each contribute to photopic visual sensitivity as measured by the b-wave of the electroretinogram (ERG). The goal of the current study was to evaluate a model of photopic b-wave spectral sensitivity in the zebrafish that mapped first-order cellular and biophysical aspects of cone photoreceptors (visual pigment absorbance spectra and cone fractions) onto a second-order physiological aspect of cone-derived neural activity in the retina. Good correspondence between the model and photopic ERG data was attained using new visual pigment absorbance data for zebrafish cones (λmax of the L, M, and S cones were 564, 473, and 407 nm, respectively), visual pigment templates, and linearly gained cone fractions. The model inferred four distinct cone processing channels that contribute to the photopic b-wave, two of which are antagonistic combinations of cone-derived signals (L-M and M-S), and two of which are noncombinatorial signals from S and U cones. The nature of the gains and the processing channels suggested general rules of cone-specific inputs to second-order neurons. The model further suggested that the zebrafish retina utilizes neuronal mechanisms for enhancing sensitivity to luminance contrast at short wavelengths and chromatic contrast at middle and long wavelengths. The results indicated that first-order cellular and biophysical aspects of cone photoreceptors can successfully explain physiological aspects of cone-derived neuronal activity in the zebrafish retina.
cGMP modulates spike responses of retinal ganglion cells via a cGMP-gated current
- FUSAO KAWAI, PETER STERLING
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- 05 September 2002, pp. 373-380
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Certain ganglion cells in the mammalian retina are known to express a cGMP-gated cation channel. We found that a cGMP-gated current modulates spike responses of the ganglion cells in mammalian retinal slice preparation. In such cells under current clamp, bath application of the membrane-permeant cGMP analog (8-bromo-cGMP, 8-p-chlorophenylthio-cGMP) or a nitric oxide donor (sodium nitroprusside, S-nitroso-N-acetyl-penicillamine) depolarized the membrane potential by 5–15 mV, and reduced the amount of current needed to evoke action potentials. Similar effects were observed when the membrane potential was simply depolarized by steady current. The responses to cGMP are unaffected by inhibitors of cGMP-dependent protein kinase and Ca2+/calmodulin-dependent protein kinase. The response to cGMP persisted in Ca2+-free bath solution with Ca2+ buffers in the pipette. Under voltage clamp, cGMP analogs did not affect the response kinetics of voltage-gated currents. We conclude that cGMP modulates ganglion cell spiking simply by depolarizing the membrane potential via the inward current through the cGMP-gated channel. Modulation of this channel via the long-range NO-synthase amacrine cell may contribute to control of contrast gain by peripheral mechanisms.
Temporal properties of optic flow responses in the ventral intraparietal area
- S.F. GABEL, H. MISSLISCH, S.J. SCHAAFSMA, J. DUYSENS
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- 05 September 2002, pp. 381-388
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The ventral intraparietal area (VIP) is located at the end of the dorsal stream. Its neurons are known to have receptive-field characteristics similar to those of MT and MST neurons, but little is known about the temporal characteristics of VIP cells' responses. How fast are directionally selective responses evoked in the ventral intraparietal area after viewing optic flow patterns, and what are the temporal properties of these neuronal responses? To examine these questions, we recorded the activity of 37 directionally selective ventral intraparietal area (VIP) neurons in two awake macaque monkeys in response to optic flow stimuli with presentation times ranging from 17 ms to 2000 ms. We found a minimum response latency of 45 ms, and a median latency of 152 ms. Of all neurons, 10% showed early response components only (response latency < 150 ms and no activity in 500–2000 ms interval after stimulus onset), 55% only late response components (response latency >150 ms and sustained activity in 500–2000 ms interval), and 35% both early and late response components. Early responses appeared to very brief stimulus presentations (33-ms duration), while the late responses required longer stimulus durations. The directional selectivity was independent of optic flow duration in all cells. These results suggest that only a subset of neurons in area VIP may contribute to the fast processing of optic flow, while showing that the temporal properties of VIP responses clearly differ from the temporal characteristics of neurons in areas MT and MST.