Research Article
Identification and localization of connexin26 within the photoreceptor-horizontal cell synaptic complex
- ULRIKE JANSSEN-BIENHOLD, KONRAD SCHULTZ, ALEXANDRA GELLHAUS, PETER SCHMIDT, JOSEF AMMERMÜLLER, RETO WEILER
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- 04 May 2001, pp. 169-178
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Connexin26 (Cx26) is a member of the family of integral membrane proteins that normally form intercellular gap junctional channels. We have used Western blotting, immunofluorescence, immunoelectron microscopy, and single-cell reverse-transcriptase polymerase chain reaction amplification (RT-PCR) to analyze the expression and cellular localization of Cx26 in the carp retina. In the outer plexiform layer, strong clustered Cx26 immunolabeling was concentrated at and restricted to the terminal dendrites of horizontal cells. Single-cell RT-PCR confirmed the expression of Cx26 in carp retinal horizontal cells. 248-bp fragments amplified from cDNAs of four different horizontal cells were cloned and each nucleotide sequence encodes a protein fragment (AA 104-185) with highly significant homology to rat and mouse Cx26. Immunoelectron microscopy revealed that only the invaginating dendrites of horizontal cells in intimate lateral association with the presynaptic ribbon complex were labeled. No labeling was found at the photoreceptor membrane and there was no septalaminar structure, indicative of gap junctions, between photoreceptors and horizontal cells. The focal location of Cx26 at the membrane of the dendritic tips of horizontal cells and the lack of gap junctional morphology suggests that Cx26 might form hemichannels.
Evidence for a visual subsector within the zona incerta
- BRIAN D. POWER, CATHERINE A. LEAMEY, JOHN MITROFANIS
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- 04 May 2001, pp. 179-186
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Here we examine the patterns of connections between the zona incerta (ZI) of the thalamus and the major visual centers of the rat brain, namely the retina, dorsal lateral geniculate nucleus (LGd), superficial layers of the superior colliculus (SCs), and occipital cortex (Oc1). Injections of the tracers biotinylated dextran or cholera toxin subunit b were made into each of these centers, as well as ZI itself, by using stereotaxic coordinates. Rat brains were then aldehyde-fixed and processed using standard methods. We show that the retina, LGd, SCs, and Oc1 all have connections with ZI; moreover, that each of these connections make a very distinct territory or subsector within the most lateral ZI regions. This subsector of connectivity with the visual centers does not respect the well-defined cytoarchitectonic sectors of ZI, being made up of small zones in the dorsal, ventral, and caudal sectors. Often, a distinctive “horse-shoe” pattern is evident, particularly after retinal and Oc1 injections. Tracer injections into topographically distinct regions of the LGd, SCs, or Oc1 results in no shift in the spatial location of labelling within ZI; after each injection, labelling is always seen within the lateral edge of the nucleus. Labelled terminals and cells are seen after LGd and SCs injections, while only labelled terminals are seen after retinal and Oc1 injections. Although the precise function of this novel visual subsector is not known, these early findings suggest that ZI may be in a position to integrate visual information together with the other somatosensory, motor, and visceral information that it receives.
Contributions of AMPA- and kainate-sensitive receptors to the photopic electroretinogram of the Xenopus retina
- T. SZIKRA, P. WITKOVSKY
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- 04 May 2001, pp. 187-196
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The effects of kainate receptor-preferring glutamate ligands were tested on the electroretinogram (ERG) of the Xenopus retina. Kainate, domoic acid, and 5-iodowillardiine (20–100 μM) acted similarly in every respect. They increased peak amplitudes of the ERG a-, b-, and d-waves significantly over controls. The AMPA-specific antagonist, GYKI 53655, prevented a kainate-induced increase in ERG a- and d-waves, but was without effect on an increase in the b-wave. Once the effect of agonist on the b-wave had peaked, the ERG began to subside, leading to its nearly complete disappearance within 20 min. Prior exposure to GYKI followed by a combination of GYKI + agonist did not significantly slow the rate of b-wave disappearance. Our results indicate that (1) AMPA receptors contribute to ERG a- and d-waves. (2) The kainate-evoked increase in ERG a-, b-, and d-waves probably results, in part, from an excitotoxic swelling of inner retinal processes. (3) The inner retina has a population of GYKI-resistant, kainate-sensitive receptors which may contribute to b-wave generation.
Sequential recovery of sensitivity to negative and positive contrasts during optic nerve regeneration in goldfish
- D.P.M. NORTHMORE, D.-J. OH
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- 04 May 2001, pp. 197-201
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A psychophysical procedure, classical conditioning of respiration, was used to measure contrast sensitivity to positive- and negative-contrast discs (8-deg diameter) in goldfish after crushing one optic nerve intraorbitally. In five out of six fish, sensitivity recovered to normal. Recovery times for negative contrasts were significantly shorter than for positive contrasts. The average times postcrush of initial responding to negative and positive contrasts were 23.8 and 30.6 days, and for threshold to come within 0.5 log unit of control values was 29.8 and 39.8 days, respectively. Thereafter, recovery to normal sensitivity was significantly faster for positive contrasts. These results parallel prior observations of neural activity in tectum after optic nerve crush: an early phase of OFF responding followed by a more sudden recovery of ON responding.
Neural and perceptual adjustments to dim light
- MATTHEW PETERSON, IZUMI OHZAWA, RALPH FREEMAN
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- 04 May 2001, pp. 203-208
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At reduced luminance levels, the visual system integrates light over extended periods of time. Although the general effects of this process are known, specific changes in the visual cortex have not been identified. We have studied the physiological changes that occur during a transition from high to low luminance by measurements of single neurons in the cat's primary visual cortex. Under low-luminance conditions, we find increased latencies, expanded temporal responses, and a loss of temporal structure. This results in temporal-frequency tuning curves that are peaked at relatively low frequencies. To examine parallel perceptual changes, we compared perceived temporal frequency in human subjects under high- and low-luminance conditions. Low-luminance flickering patterns are perceived to modulate at relatively high rates. This occurs even though peak sensitivity is shifted to relatively low temporal frequencies. To explore further the perceptual component, we measured perceived temporal frequency in human subjects with unilateral optic neuritis for whom optic nerve transmission is known to be relatively slow and generally similar to the normal physiological state under low luminance. These subjects also perceive relatively high modulation rates through their affected eye. Considered together, these results demonstrate an inverse relationship between the physiological and the perceptual consequences of reduced stimulus luminance. This relationship may be accounted for by shifts of neuronal population responses between high- and low-luminance levels.
Long-range interactions in the lateral geniculate nucleus of the New-World monkey, Callithrix jacchus
- FATIMA FELISBERTI, ANDREW M. DERRINGTON
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- 04 May 2001, pp. 209-218
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Visual stimulation of zones extending beyond the classical receptive field can modulate the contrast gain of neurons in the lateral geniculate nucleus (LGN) of cats, but little is known about the effect of extra-classical visual stimulation on the LGN of primates. Hence, we compare the effect of long-range interactions in parvocellular and magnocellular LGN layers of the marmoset monkey Callithrix jacchus using optimal, incremental spots flashed on the classical receptive field either alone or simultaneously with the shift of a grating (98% contrast; 0.1 cycles/deg) confined to a peripheral annulus (radii: 5–15 deg). The contrast required to drive the response halfway to saturation (c50) of most LGN neurons was raised by remote pattern shifts. The c50 ratio [(shift+spot)/spot] in OFF-center magnocellular neurons was significantly higher than in OFF-center parvocellular neurons. OFF-center magnocellular neurons closer to the fovea (<10 deg eccentricity) tended to have a higher c50 ratio than in more peripheral neurons. A significant drop in visual sensitivity to 25% contrast spots was observed during remote motion: d′ fell from 1.8 to 1.4 in parvocellular neurons and from 2.2 to 1.7 in magnocellular neurons. Such long-range interactions produce a reduction in visual sensitivity by changing the gain of the geniculate relay and point to an inhibitory, motion-sensitive extra-classical receptive field in both parvocellular and magnocellular pathways, which may be involved in saccadic suppression and attentional mechanisms in early vision.
Dynamic properties of retino-geniculate synapses in the cat
- MICHAEL H. ROWE, QUENTIN FISCHER
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- 04 May 2001, pp. 219-231
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Simultaneous recordings from relay cells in the lateral geniculate nucleus (LGN) and their retinal afferents were used to examine the rules governing the transmission of spikes across the retino-geniculate synapse. Retinal spikes that terminate short retinal interspike intervals are much more likely to be transmitted across the synapse than spikes terminating longer intervals. This facilitation can be observed for interspike intervals as long as 50 ms when retinal firing rates are low, but the range of effective intervals decreases exponentially as retinal firing rate increases. Contribution, the fraction of LGN spikes triggered by an individual retinal afferent, is typically much higher during visual stimulation than during maintained activity, and these differences are unrelated to presynaptic or postsynaptic firing rate. It is suggested that this effect is a manifestation of increased synchronization of spikes among retinal afferents to the geniculate cell during structured visual stimulation, and that this synchronization offers a means of enhancing signal-to-noise ratio at the retino-geniculate synapse. Cross-correlograms between geniculate burst spikes and retinal afferents often contain two distinct peaks; a short latency peak that results from direct coupling between burst spikes and retinal input spikes, and a longer latency peak that represents indirect coupling in which retinal spikes trigger the calcium spike underlying the burst. Direct coupling is most likely to occur for the later spikes in the burst, and is present regardless of whether the calcium spike underlying the burst is triggered by the same or a different retinal afferent. These results further illuminate the relationship between tonic and burst modes of retino-geniculate transmission and indicate that bursts in LGN relay cells can be viewed as a mechanism of signal amplification, producing signals whose timing is potentially related to the temporal structure of a stimulus, independent of presynaptic and postsynaptic firing rate. This mechanism also appears to capitalize on the synchronization that is present among parallel retinal afferents to a geniculate cell.
Organization of the inner retina following early elimination of the retinal ganglion cell population: Effects on cell numbers and stratification patterns
- R.R. WILLIAMS, K. CUSATO, M.A. RAVEN, B.E. REESE
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- 04 May 2001, pp. 233-244
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The present study has examined the effects of early ganglion cell elimination upon the organization of the inner retina in the ferret. The population of retinal ganglion cells was removed by optic nerve transection on the second postnatal day, and retinas were subsequently studied in adulthood. Numbers of amacrine and bipolar cells were compared in the nerve-transected and nerve-intact retinas of operated ferrets, while stratification patterns within the inner plexiform layer were compared in these and in normal ferret retinas. Early ganglion cell elimination was found to produce a 25% reduction in the population of glycine transporter-immunoreactive amacrine cells, and 18 and 15% reductions in the populations of parvalbumin and calbindin-immunoreactive amacrine cells, respectively. GABAergic amacrine cells were also reduced by 34%. The number of calbindin-immunoreactive displaced amacrine cells, by contrast, had increased in the ganglion cell-depleted retina, being three times their normal number. Other amacrine and bipolar cell types were unaffected. Despite these changes, the stratification patterns associated with these cell types remained largely intact within the inner plexiform layer. The present results demonstrate a class-specific dependency of inner retinal neurons upon the ganglion cell population in early postnatal life, but the ganglion cells do not appear to provide any critical signals for stratification within the inner plexiform layer, at least not after birth. Since they themselves do not produce stratified dendritic arbors until well after birth, the signals for stratification of the bipolar and amacrine cell processes should arise from other sources.
Rod photopigment deficits in albinos are specific to mammals and arise during retinal development
- SIMON GRANT, NEHA N. PATEL, ALISDAIR R. PHILP, CHARLOTTE N.B. GREY, RICHARD D. LUCAS, RUSSELL G. FOSTER, JAMES K. BOWMAKER, GLEN JEFFERY
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- 04 May 2001, pp. 245-251
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Adult albino mammals have specific retinal defects, including reduced numbers of rod photoreceptors. To examine when this rod deficit arises and whether it exists in nonmammalian albinos, we have used absorbance spectrophotometry to measure photopigment levels in dark-adapted eyes taken from three groups of pigmented and albino animals: adult rodents (rats and mice), developing rats, and mature Xenopus frogs. Rhodopsin concentrations were consistently and significantly reduced in mammalian albinos compared to their wild-type counterparts from before the time of eye opening, but photopigment levels were similar in frogs of both pigmentation phenotypes. The results strongly suggest that deficits in the rod cell population arise early in development of the mammalian albino retina, but do not generalize to nonmammalian mutants lacking retinal melanin.
The effects of saccadic eye movements on the activity of geniculate relay neurons in the monkey
- E.J. RAMCHARAN, J.W. GNADT, S.M. SHERMAN
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- 04 May 2001, pp. 253-258
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Saccadic suppression is the reduced visibility that occurs during saccadic eye movements. Recent psychophysical studies have suggested that this is due to a reduction in responsiveness of magnocellular (M), but not parvocellular (P), cells of the lateral geniculate nucleus. To address this and other phenomena of responsiveness during saccades, we recorded from geniculate neurons in the behaving monkey before, during, and after saccades. Specifically, we measured neuronal responses to a flashing, whole-field illumination. Contrary to the prediction, most M neurons showed pronounced enhancement of visual activity during saccades, whereas such responsiveness of parvocellular (P) neurons was not significantly affected by saccades. We also analyzed the extent to which saccades affected burst firing, which results from activation of a voltage-dependent Ca2+ conductance. We found that both M and P cells displayed a significant suppression of burst firing during saccades. These results do not support the idea that saccadic suppression has an obvious substrate in reduced responsiveness of geniculate cells, but this suppression may be related to an increased visual threshold for detection associated with reduced burst firing.
Selective activation of visual cortex neurons by fixational eye movements: Implications for neural coding
- D. MAX SNODDERLY, IGOR KAGAN, MOSHE GUR
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- 04 May 2001, pp. 259-277
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During normal vision, when subjects attempt to fix their gaze on a small stimulus feature, small fixational eye movements persist. We have recorded the impulse activity of single neurons in primary visual cortex (V1) of macaque monkeys while their fixational eye movements moved the receptive-field activating region (AR) over and around a stationary stimulus. Three types of eye movement activation were found. (1) Saccade cells discharged when a fixational saccade moved the AR onto the stimulus, off the stimulus, or across the stimulus. (2) Position/drift cells discharged during the intersaccadic (drift) intervals and were not activated by saccades that swept the AR across the stimulus without remaining on it. To activate these neurons, it was essential that the AR be placed on the stimulus and many of these cells were selective for the sign of contrast. They had smaller ARs than the other cell types. (3) Mixed cells fired bursts of activity immediately following saccades and continued to fire at a lower rate during intersaccadic intervals. The tendency of each neuron to fire transient bursts or sustained trains of impulses following saccades was strongly correlated with the transiency of its response to stationary flashed stimuli. For one monkey, an extraretinal influence accompanying fixational saccades was identified. During natural viewing, the different eye movement classes probably make different contributions to visual processing. Position/drift neurons are well suited for coding spatial details of the visual scene because of their small AR size and their selectivity for sign of contrast and retinal position. However, saccade neurons transmit information that is ambiguous with respect to the spatial details of the retinal image because they are activated whether the AR lands on a stimulus contour, or the AR leaves or crosses the contour and lands in another location. Saccade neurons may be involved in constructing a stable world in spite of incessant retinal image motion, as well as in suppressing potentially confusing input associated with saccades.
Voltage-activated Ca2+ channels and ionotropic GABA receptors localized at axon terminals of mammalian retinal bipolar cells
- ZHUO-HUA PAN
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- 04 May 2001, pp. 279-288
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A preparation of isolated presynaptic terminals of rat retinal rod bipolar cells was developed. Patch-clamp recordings were performed on the isolated terminal to determine the type(s) of voltage-activated Ca2+ channels and the contribution of GABAA and GABAC receptor-mediated currents localized in the terminal region. Both low-voltage-activated (LVA) and high-voltage-activated (HVA) Ca2+ currents, with properties similar to those found in intact cell recordings, were observed in the isolated terminal recordings. Consistent with previous studies, the HVA Ca2+ currents are L-type since the currents were blocked by low micromolar concentrations of nimodipine and potentiated by BayK 8644. Also, both GABAA and GABAC receptor-mediated currents were observed in the isolated terminal. The current density of GABAC receptors in the terminal was more than three times higher than that in the soma. In contrast, the current density of GABAA currents between the terminal and the soma was not significantly different. Assessed by 100 μM GABA, the contributions of GABAA and GABAC receptors to the total GABA-mediated currents at the terminal were comparable. This study directly demonstrates the localization of LVA Ca2+ channels at the axon terminal of mammalian rod bipolar cells, suggesting that LVA Ca2+ channels may play a role in bipolar cell transmitter release. Results of this study also support the notion that both types of ionotropic GABA receptors regulate synaptic transmission in mammalian rod bipolar cells. In addition, this study reports for the first time the feasibility of direct patch-clamp recordings of isolated axon terminals of mammalian retinal bipolar cells. The isolated presynaptic terminal preparation of mammalian retinal bipolar cells could be a valuable system for the study of transmitter release in the central nervous system (CNS).
Evidence for spatial regularity among retinal ganglion cells that project to the accessory optic system in a frog, a reptile, a bird, and a mammal
- JEREMY E. COOK, TATYANA A. PODUGOLNIKOVA
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- 04 May 2001, pp. 289-297
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The vertebrate retina contains only five major neuronal classes but these embrace a great diversity of discrete types, many of them hard to define by classical methods. Consideration of their spatial distributions (mosaics) has allowed new types, including large ganglion cells, to be resolved across a wide range of vertebrates. However, one category of large ganglion cells has seemed refractory to mosaic analysis: those that project to the accessory optic system (AOS) and serve vestibulocerebellar mechanisms of motion detection and image stabilization. Whenever AOS-projecting cells have been analyzed by nearest-neighbor methods, their distribution has appeared almost random. This is puzzling, because most aspects of visual processing require the visual scene to be sampled regularly. Here, spatial correlogram methods are applied to distributions of large ganglion cells, labeled retrogradely from the AOS in frogs, turtles, and rats, and to the AOS-projecting displaced ganglion cells of chickens. These methods reveal hidden spatial order among AOS-projecting populations, of a form that can be simulated either by superimposing a single regular mosaic on a random population or, more interestingly, by overlapping three or more regular, similar but spatially independent mosaics. The rabbit is known to have direction-selective ganglion cells (not, however, AOS projecting) that can be subdivided into functionally distinct, regular mosaics by their tracer-coupling patterns even though they are morphologically homogeneous. The present results imply that the direction-selective AOS-projecting ganglion cells of all vertebrates may, likewise, be subdivided into regular, independent mosaics.
Functional and morphological assessment of age-related changes in the choroid and outer retina in pigeons
- MALINDA E.C. FITZGERALD, ELIZABETH TOLLEY, SHARON FRASE, YURI ZAGVAZDIN, RONALD F. MILLER, WILLIAM HODOS, ANTON REINER
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- 04 May 2001, pp. 299-317
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We sought to determine if choroidal and outer retinal deterioration occur with age in pigeons, as they do in other species, and investigated the relationship between age-related retinal and choroidal changes. In 64 pigeons ranging in age over the pigeon lifespan (0.5–20 years), we measured some or all among the following parameters: choroidal blood flow (ChBF) by laser Doppler flowmetry, choroidal thickness and choriocapillary vessel abundance by LM histology, choriocapillary endothelial cell transport specializations by EM histology, acuity by behavioral methods, and degenerating photoreceptor abundance and total photoreceptor abundance by LM histology. Regression and Receiver Operator Curve (ROC) analyses were used to characterize the pattern of age-related changes and determine the ages at or by which significant changes occurred. For the 45 birds for which we measured choroidal parameters, choriocapillary vessel abundance showed a curvilinear decline with age and half of this decline occurred by 3.5–4.6 years. The endothelial cell transport specializations called channels also declined curvilinearly with age. Choroidal thickness was slightly increased between the ages of 3–6 years, and thereafter declined steadily so that choroidal thickness in the oldest birds was half that in the youngest. ChBF showed an abrupt decline of about 20% at 4 years and a further 20% decline thereafter. In the 53 birds for which we obtained visual acuity and/or photoreceptor data, we observed a curvilinear decline in acuity (with half the decline having occurred by 8 years) and a prominent stepwise decline of about 20% in photoreceptor abundance at 4.7 years, followed by further decline thereafter. The period of major photoreceptor loss coincided with ages during which about 10% of photoreceptors appeared to show degenerative changes (4–8 years of age). Using partial correlation analysis with the common effect of age held constant, ChBF was found to have a positive correlation with acuity. Our results show that ChBF and choroidal vascularity decline significantly with age in pigeons, as do acuity and photoreceptor abundance. Our statistical analyses suggest that prominent choroidal vascular decline preceded the visual decline, and that there is a positive relationship between choroidal and visual functions. Thus, our findings are consistent with the view that age-related decline in choroidal function might contribute to age-related vision loss in pigeons.
A comparative morphometric analysis of the optic nerve in two cetacean species, the striped dolphin (Stenella coeruleoalba) and fin whale (Balaenoptera physalus)
- ANDREA MAZZATENTA, MATTEO CALEO, NATALE EMILIO BALDACCINI, LAMBERTO MAFFEI
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- 04 May 2001, pp. 319-325
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A comparative study was made on one Mysticete (the fin whale, Balaenoptera physalus) and one Odontocete species (the striped dolphin, Stenella coeruleoalba) by measuring several morphological characteristics seen in cross sections of the optic nerve. We found that the two cetacean nerves share a number of specializations that distinguish them from the optic nerve of terrestrial mammals. Fiber density is approximately two-fold lower than in land mammals. A corresponding increase in the cross-sectional area occupied by astrocytes is observed. A population of “giant” (up to 15 μm in diameter) optic axons is present in both the B. physalus and the S. coeruleoalba nerve. It is argued that these features probably reflect common adaptations to the constraints imposed by the aquatic environment. “Giant” optic axons might ensure short-latency detection of preys and other targets during navigation while the increased astroglial content might be related to the maintenance of neuronal function during periods of anaerobic metabolism under water.
Dopamine depletion with 6-OHDA enhances dopamine D1-receptor modulation of potassium currents in retinal bipolar cells
- SHIH-FANG FAN, STEPHEN YAZULLA
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- 04 May 2001, pp. 327-337
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Ascorbate modulates IK(V) of ON-type mixed rod/cone bipolar cells (Mb) in the goldfish retinal slice through a dopamine D1/G-protein/PKA-coupled mechanism. We investigated the effects of dopamine depletion with intraocular injections of 6-OHDA on IK(V) and its modulation by ascorbate over 1–7 weeks following 6-OHDA treatment. Dopamine depletion was verified by tyrosine hydroxylase immunocytochemistry. Slices were perfused in a saline containing 200 μM sodium ascorbate. One-second puffs of ascorbate-free saline (zero [AA]o), delivered through a 2–3 μm diameter pipette, were directed at the bipolar cells. IK(V) was recorded by conventional whole-cell patch-clamp methods. In normal retinas, puffs of zero [AA]o caused a rapid (<100 ms) suppression of IK(V) of about 50% that lasted for several minutes. This effect was blocked by 1 μM SCH23390 and was unaffected by 2 mM Co2+ or 5 μM spiperone. 6-OHDA treatment resulted in major effects. First, IK(V) was reduced by ∼50% for weeks 1–6, recovering to a 20% reduction by week 7. Second, puffs of zero [AA]o enhanced IK(V) rather than suppressed it. The enhancement was blocked by SCH23390 and the PKA inhibitor, Wiptide, but was insensitive to spiperone. Third, all parts of the Mb bipolar cell (except for the axon) were sensitive to puffs of zero [AA]o in both normal and 6-OHDA-treated retinas. Fourth, bath application of 20 μM dopamine restored the amplitude of IK(V) but did not reverse the effects of puffed zero [AA]o. IK(V) was fit by two exponentials; all of the effects on IK(V) were on the amplitude of the components and not on the time constants. Chronic dopamine depletion caused reversible changes in the properties of K+ channels underlying IK(V), as well as a long-term change in the intracellular coupling mechanisms between D1-receptor activation and the modulation of IK(V).