Research Article
A model of high-frequency oscillatory potentials in retinal ganglion cells
- GARRETT T. KENYON, BARTLETT MOORE, JANELLE JEFFS, KATE S. DENNING, GREG J. STEPHENS, BRYAN J. TRAVIS, JOHN S. GEORGE, JAMES THEILER, DAVID W. MARSHAK
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- Published online by Cambridge University Press:
- 22 January 2004, pp. 465-480
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High-frequency oscillatory potentials (HFOPs) have been recorded from ganglion cells in cat, rabbit, frog, and mudpuppy retina and in electroretinograms (ERGs) from humans and other primates. However, the origin of HFOPs is unknown. Based on patterns of tracer coupling, we hypothesized that HFOPs could be generated, in part, by negative feedback from axon-bearing amacrine cells excited via electrical synapses with neighboring ganglion cells. Computer simulations were used to determine whether such axon-mediated feedback was consistent with the experimentally observed properties of HFOPs. (1) Periodic signals are typically absent from ganglion cell PSTHs, in part because the phases of retinal HFOPs vary randomly over time and are only weakly stimulus locked. In the retinal model, this phase variability resulted from the nonlinear properties of axon-mediated feedback in combination with synaptic noise. (2) HFOPs increase as a function of stimulus size up to several times the receptive-field center diameter. In the model, axon-mediated feedback pooled signals over a large retinal area, producing HFOPs that were similarly size dependent. (3) HFOPs are stimulus specific. In the model, gap junctions between neighboring neurons caused contiguous regions to become phase locked, but did not synchronize separate regions. Model-generated HFOPs were consistent with the receptive-field center dynamics and spatial organization of cat alpha cells. HFOPs did not depend qualitatively on the exact value of any model parameter or on the numerical precision of the integration method. We conclude that HFOPs could be mediated, in part, by circuitry consistent with known retinal anatomy.
Center-surround organization in bipolar cells: Symmetry for opposing contrasts
- PATRICK K. FAHEY, DWIGHT A. BURKHARDT
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- 13 March 2003, pp. 1-10
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Intracellular recordings were obtained from 73 cone-driven bipolar cells in the light-adapted retina of the tiger salamander (Ambystoma tigrinum). Responses to flashes of negative and positive contrast for centered spots and concentric annuli of optimum spatial dimensions were analyzed as a function of contrast magnitude. For both depolarizing and hyperpolarizing bipolar cells, it was found that remarkably similar responses were observed for the center and surround when comparisons were made between responses of the same response polarity and thus, responses to opposite contrast polarity. Thus, spatial information and contrast polarity appear to be rather strongly confounded in many bipolar cells. As a rule, the form of the contrast/response curves for center and surround approximated mirror images of each other. Contrast gain and C50 (the contrast required for half-maximal response) were quantitatively similar for center and surround when comparisons were made for responses of the same response polarity. The average contrast gain of the bipolar cell surround was 3–5 times higher than that measured for horizontal cells. Contrast/latency measurements and interactions between flashed spots and annuli showed that the surround response is delayed by 20–80 ms with respect to that of the receptive-field center. Cones showed no evidence for center-surround antagonism while for bipolar cells, the average strength of the surround ranged from about 50% to 155% of the center, depending on the test and response polarity. The results of experiments on the effects of APB (100 μM) on depolarizing bipolar cells suggest that the relative contribution of the feedback pathway (horizontal cell to cones) and the feedforward pathway (horizontal cell to bipolar cell) to the bipolar surround varies in a distributed manner across the bipolar cell population.
Gain control from beyond the classical receptive field in primate primary visual cortex
- BEN S. WEBB, CHRIS J. TINSLEY, NICK E. BARRACLOUGH, AMANDA PARKER, ANDREW M. DERRINGTON
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- 03 October 2003, pp. 221-230
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Gain control is a salient feature of information processing throughout the visual system. Heeger (1991, 1992) described a mechanism that could underpin gain control in primary visual cortex (V1). According to this model, a neuron's response is normalized by dividing its output by the sum of a population of neurons, which are selective for orientations covering a broad range. Gain control in this scheme is manifested as a change in the semisaturation constant (contrast gain) of a V1 neuron. Here we examine how flanking and annular gratings of the same or orthogonal orientation to that preferred by a neuron presented beyond the receptive field modulate gain in V1 neurons in anesthetized marmosets (Callithrix jacchus). To characterize how gain was modulated by surround stimuli, the Michaelis–Menten equation was fitted to response versus contrast functions obtained under each stimulus condition. The modulation of gain by surround stimuli was modelled best as a divisive reduction in response gain. Response gain varied with the orientation of surround stimuli, but was reduced most when the orientation of a large annular grating beyond the classical receptive field matched the preferred orientation of neurons. The strength of surround suppression did not vary significantly with retinal eccentricity or laminar distribution. In the marmoset, as in macaques (Angelucci et al., 2002a, b), gain control over the sort of distances reported here (up to 10 deg) may be mediated by feedback from extrastriate areas.
A comparison of immunocytochemical markers to identify bipolar cell types in human and monkey retina
- SILKE HAVERKAMP, FRANCOISE HAESELEER, ANITA HENDRICKSON
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- 30 March 2004, pp. 589-600
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As more human retinas affected with genetic or immune-based diseases become available for morphological analysis, it is important to identify immunocytochemical markers for specific subtypes of retinal neurons. In this study, we have focused on bipolar cell markers in central retina. We have done single and double labeling using several antisera previously utilized in macaque monkey or human retinal studies and two new antisera (1) to correlate combinations of antisera labeling with morphological types of bipolar cells in human retina, and (2) to compare human labeling patterns with those in monkey retina. Human bipolar cells showed a wide range of labeling patterns with at least ten different bipolar cell types identified from their anatomy and marker content. Many bipolar cell bodies in the outer part of the inner nuclear layer contained combinations of protein kinase C alpha (PKCα), Islet-1, glycine, and Goα. Bipolar cells labeled with these markers had axons terminating in the inner half of the inner plexiform layer (IPL), consistent with ON bipolar cells. Bipolar cell bodies adjacent to the amacrine cells and with axons in the outer half of the IPL contained combinations of recoverin, glutamate transporter-1, and PKCβ, or CD15 and calbindin. Bipolar cells labeled with these markers were presumed OFF bipolar cells. Calcium-binding protein 5 (CaB5) labeled both putative ON and OFF bipolar cells. Using this cell labeling as a criteria, most cell bodies close to the horizontal cells were ON bipolar cells and almost all bipolar cells adjacent to the amacrine cells were OFF with a band in the middle 2–3 cell bodies thick containing intermixed ON and OFF bipolar cells. Differences were found between human and monkey bipolar cell types labeled by calbindin, CaB5, and CD15. Two new types were identified. One was morphologically similar to the DB3, but labeled for CD15 and CaB5. The other had a calbindin-labeled cell body adjacent to the horizontal cell bodies, but did not contain any accepted ON markers. These results support the use of macaque monkey retina as a model for human, but caution against the assumption that all labeling patterns are identical in the two primates.
Inhibitory network properties shaping the light evoked responses of cat alpha retinal ganglion cells
- BRENDAN J. O'BRIEN, RANDAL C. RICHARDSON, DAVID M. BERSON
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- 18 November 2003, pp. 351-361
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Cat retinal ganglion cells of the Y (or alpha) type respond to luminance changes opposite those preferred by their receptive-field centers with a transient hyperpolarization. Here, we examine the spatial organization and synaptic basis of this light response by means of whole-cell current-clamp recordings made in vitro. The hyperpolarization was largest when stimulus spots approximated the size of the receptive-field center, and diminished substantially for larger spots. The hyperpolarization was largely abolished by bath application of strychnine, a blocker of glycinergic inhibition. Picrotoxin, an antagonist of ionotropic GABA receptors, greatly reduced the attenuation of the hyperpolarizing response for large spots. The data are consistent with a model in which (1) the hyperpolarization reflects inhibition by glycinergic amacrine cells of bipolar terminals presynaptic to the alpha cells, and perhaps direct inhibition of the alpha cell as well; and (2) the attenuation of the hyperpolarization by large spots reflects surround inhibition of the glycinergic amacrine by GABAergic amacrine cells. This circuitry may moderate nonlinearities in the alpha-cell light response and could account for some excitatory and inhibitory influences on alpha cells known to arise from outside the classical receptive field.
Involvement of glutamate in ischemic neurodegeneration in isolated retina
- YUKITOSHI IZUMI, SETH B. HAMMERMAN, CHARITY O. KIRBY, ANN M. BENZ, JOHN W. OLNEY, CHARLES F. ZORUMSKI
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- 26 June 2003, pp. 97-107
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Retinal ischemia, a major cause of visual loss, is believed to result from overexcitation of glutamate receptors. However, under euglycemic and normoxic conditions, exogenously applied glutamate is not neurotoxic in the retina. Under such conditions, exogenous glutamate typically causes glia swelling and requires very high concentrations to produce neurotoxicity. To determine whether ischemic conditions enhance the neurotoxicity of endogenous and exogenous glutamate, we examined the effects of simulated ischemia (deprivation of both glucose and oxygen) on retinal morphology and lactate dehydrogenase (LDH) release. In an ex vivo rat retinal preparation, glutamate was administered during simulated ischemia in the presence of riluzole, an inhibitor of glutamate release. Deprivation of both glucose and oxygen for 60 min at 30°C produced severe acute neurodegeneration. This neurodegeneration, characterized by bull's eye formation in the inner nuclear layer and spongy appearance in the inner plexiform layer, was prevented by the combination of MK-801 and DNQX, antagonists of N-methyl-D-aspartate (NMDA) and non-NMDA receptors, indicating that the damage results from activation of both glutamate receptors. We also found that administration of glutamate pyruvate transaminase (alanine aminotransaminase) with pyruvate diminished the neurodegeneration during simulated ischemia. Furthermore, riluzole, an inhibitor of glutamate release, attenuated the neurodegeneration, suggesting the importance of endogenous glutamate in ischemic damage. In the presence of riluzole and simulated ischemia, exogenously applied glutamate failed to cause Müller cell swelling but was extremely neurotoxic. These results suggest that simulated ischemia enhances glutamate-mediated neurotoxicity in part by depressing glutamate uptake. When glutamate transport is impaired, sub-millimolar glutamate concentrations become profoundly neurotoxic.
Temporal modulation sensitivity of tree shrew retinal ganglion cells
- HAIDONG D. LU, HEYWOOD M. PETRY
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- 18 November 2003, pp. 363-372
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Tree shrews (Tupaia belangeri) are small diurnal mammals capable of quick and agile navigation. Electroretinographic and behavioral studies have indicated that tree shrews possess very good temporal vision, but the neuronal mechanisms underlying that temporal vision are not well understood. We used single-unit extracellular recording techniques to characterize the temporal response properties of individual retinal ganglion cell axons recorded from the optic tract. A prominent characteristic of most cells was their sustained or transient nature in responding to the flashing spot. Temporal modulation sensitivity functions were obtained using a Gaussian spot that was temporally modulated at different frequencies (2–60 Hz). Sustained cells respond linearly to contrast. They showed an average peak frequency of 6.9 Hz, a high-frequency cutoff at 31.3 Hz, and low-pass filtering. Transient cells showed nonlinear response to contrast. They had a peak frequency of 19.3 Hz, a high-frequency cutoff at about 47.6 Hz, band-pass filtering, and higher overall sensitivity than sustained cells. The responses of transient cells also showed a phase advance of about 88 deg whereas the phase advance for sustained cells was about 43 deg. Comparison with behavioral temporal modulation sensitivity results suggested that transient retinal ganglion cells may underlie detection for a wide range of temporal frequencies, with sustained ganglion cells possibly mediating detection below 4 Hz. These data suggest that two well-separated temporal channels exist at the retinal ganglion cell level in the tree shrew retina, with the transient channel playing a major role in temporal vision.
Retinal projections in the cat: A cholera toxin B subunit study
- ISABELLE MATTEAU, DENIS BOIRE, MAURICE PTITO
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- 22 January 2004, pp. 481-493
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The B fragment of cholera toxin (CTb) is a highly sensitive anterograde tracer for the labelling of retinal axons. It can reveal dense retinofugal projections to well-known retinorecipient nuclei along with sparse but distinct input to target areas that are not commonly recognized. Following a unilateral injection of CTb into the vitreous chamber of seven adult cats, we localized the toxin immunohistochemically in order to identify direct retinal projections in these animals. Consistent with previous findings, the strongest projections were observed in the superficial layers of the superior colliculus, the dorsal and ventral lateral geniculate nuclei, the pretectal nuclei, the accessory optic nuclei, and the suprachiasmatic nucleus of the hypothalamus. However, we also found labelled terminals in several other brain areas, including the zona incerta, the medial geniculate nucleus, the lateral posterior-pulvinar complex, the lateral habenular nucleus, and the anterior and lateral hypothalamic regions. The morphological characteristics of the retinal axon terminals in most of the identified novel target sites are described.
Melanopsin and non-melanopsin expressing retinal ganglion cells innervate the hypothalamic suprachiasmatic nucleus
- PATRICIA J. SOLLARS, CYNTHIA A. SMERASKI, JESSICA D. KAUFMAN, MALCOLM D. OGILVIE, IGNACIO PROVENCIO, GARY E. PICKARD
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- 30 March 2004, pp. 601-610
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Retinal input to the hypothalamic suprachiasmatic nucleus (SCN) synchronizes the SCN circadian oscillator to the external day/night cycle. Retinal ganglion cells that innervate the SCN via the retinohypothalamic tract are intrinsically light sensitive and express melanopsin. In this study, we provide data indicating that not all SCN-projecting retinal ganglion cells express melanopsin. To determine the proportion of ganglion cells afferent to the SCN that express melanopsin, ganglion cells were labeled following transsynaptic retrograde transport of a recombinant of the Bartha strain of pseudorabies virus (PRV152) constructed to express the enhanced green fluorescent protein (EGFP). PRV152 injected into the anterior chamber of the eye retrogradely infects four retinorecipient nuclei in the brain via autonomic circuits to the eye, resulting in transneuronally labeled ganglion cells in the contralateral retina 96 h after intraocular infection. In animals with large bilateral lesions of the lateral geniculate body/optic tract, ganglion cells labeled with PRV152 are retrogradely infected from only the SCN. In these animals, most PRV152-infected ganglion cells were immunoreactive for melanopsin. However, a significant percentage (10–20%) of EGFP-labeled ganglion cells did not express melanopsin. These data suggest that in addition to the intrinsically light-sensitive melanopsin-expressing ganglion cells, conventional ganglion cells also innervate the SCN. Thus, it appears that the rod/cone system of photoreceptors may provide signals to the SCN circadian system independent of intrinsically light-sensitive melanopsin ganglion cells.
The sensitivity and spectral identity of the cones driving the b-wave of the rat electroretinogram
- JAMES D. AKULA, ARKADY L. LYUBARSKY, FRANK NAARENDORP
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- 26 June 2003, pp. 109-117
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In the retina of rat, cones make up ∼0.85% of the photoreceptor population: 93% of these cones contain a midwave-sensitive pigment, the rest expresses a short-wave-sensitive pigment (Szel & Rohlich, 1992). We used normal adult Long Evans rats to determine the spectral sensitivity of the cone-driven electroretinogram (ERG) b-wave and its absolute sensitivity at λmax of the cone pigments. ERGs were recorded at the cornea of anesthetized animals under dark- and light-adapted conditions. Rod responses were suppressed by steady rod-saturating orange backgrounds and/or by a flashed “white” background. Cone-driven b-waves were evoked by “white” or narrowband full-field stimuli of varying intensity. The action spectrum for the cone b-wave indicates the presence of an absorbance peak at 510 nm; a second, twofold lower, peak was found at 360 nm (after correction for transmittance by the lens). Chromatic adaptation experiments strongly suggest that retinal responses to midwave and UV stimuli are mediated by a single cone type. On a background producing ∼17,000 R* rod−1 s−1, which completely suppressed the saturated a-wave, the absolute sensitivity of the cone b-wave was 18 nV photon−1 μm2 at 510 nm and 4 nV photon−1 μm2 at 360 nm which is 20–30 times higher than for the mouse. It is suggested that the relatively large number of on-cone bipolar cells in the retina of rat is responsible for the remarkable sensitivity of the cone b-wave.
Structure of glutamate analogs that activate the ON bipolar cell metabotropic glutamate receptor in vertebrate retina
- NING TIAN, MALCOLM M. SLAUGHTER
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- 23 September 2003, pp. 231-240
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Although there are many glutamate receptors in the retina, 2-amino-4-phosphonobutyrate (L-AP4) is an agonist that acts selectively at metabotropic glutamate receptors (mGluR6) of ON bipolar cells. We explored the properties of agonists that activate this receptor. The effects of various glutamate analogs on the b-wave of the electroretinogram (ERG) were used as a measure of their activity. Conformational comparisons among agonists suggest that ligands in an extended conformation preferentially bind to the ON bipolar synaptic receptor. But this property is insufficient to explain the selectivity of mGluR6 because some inactive glutamate analogs could also match this extended conformation. Comparative molecular field analysis (CoMFA) was used to compare the electrostatic and steric potentials of agonists with their action at the ON bipolar synapse. Steric potentials beneath a plane defined by the three putative binding sites plays a key role in determining agonist activity. The CoMFA model was used to predict the activity of glutamate analogs and correlations between predicted and measured activity support the model.
Spectral properties and retinal distribution of ferret cones
- JACK B. CALDERONE, GERALD H. JACOBS
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- 13 March 2003, pp. 11-17
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The spectral mechanisms of the ferret (Mustela putorious furo) were studied with electroretinogram (ERG) flicker photometry. Variations in adaptation state and flicker rate were used to define corneally based spectral sensitivities for the three classes of receptor present in the retina of this mustelid—rods (λmax = 505 nm), S cones (430 nm), and L cones (558 nm). The retinal distributions of the two classes of cone were determined using opsin antibody labeling. Ferret retinas contain a total of about 1.3 million cones with L cones outnumbering S cones in a ratio of approximately 14:1. ERGs were also recorded using 18.75-Hz flickering stimuli that were designed to isolate signals from individual cone classes. The contrast/response functions for signals originating from both S and L cones were linear over low-to-moderate levels of contrast, but with greatly different slopes for the two cone types. The L:S contrast gain ratio derived from a comparison of these slopes, as well as inferences drawn from another experiment in which responses to various combinations of L- and S-cone activation were analyzed, suggest that contributions of these two cone types to the flicker ERG have a relative weighting of about 4:1 to 5:1 (L/S).
Video-rate and continuous visual stimuli do not produce equivalent response timings in visual cortical neurons
- TIMOTHY J. GAWNE, JILL M. WOODS
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- 22 January 2004, pp. 495-500
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Video cathode ray tube (CRT) technology has proven to be extremely valuable for performing research in the visual system. However, the image on a CRT monitor is not constant, but consists of a series of brief pulses. This has implications for any study that explores the responses of neurons in the visual system on short time scales. In particular, there is no unambiguous time point at which a visual stimulus presented via CRT may be said to have ended. Recordings from single units in visual cortical area V1 of an awake primate demonstrate that, when studying changes in response timing on the order of 10 ms or less, stimuli delivered at video frame rates do not duplicate the effects seen with stimuli that have continuous functions of luminance versus time. Additionally, there does not seem to be any clear method of comparing the results obtained with video-rate stimuli with results obtained with continuous-time stimuli that holds for all conditions. These effects are especially critical when exploring the time course of the neuronal responses to the ending of a visual stimulus (off-response). Our findings cast doubt upon the recently reported result that off-responses have consistently shorter latencies than on-responses.
Activation of protein kinase C reduces GLAST in the plasma membrane of rat Müller cells in primary culture
- ZHIQING WANG, WEI LI, CHERYL K. MITCHELL, LOUVENIA CARTER-DAWSON
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- 30 March 2004, pp. 611-619
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In this study, a Müller cell culture preparation from young rats was used to investigate the regulation of GLAST transport activity in native cells. Immunohistochemical analysis confirmed GLAST to be the predominant glutamate transporter expressed by the cells through five passages. [3H]-glutamate uptake assays showed the typical Na+-dependent glutamate transport which was blocked by L-(-)-threo-3-hydroxyaspartate (L-THA), a competitive inhibitor. Glutamate transport was decreased significantly in Müller cells exposed to phorbol-12-myristate-13-acetate (PMA), a protein kinase C (PKC) activator. A similar effect on [3H]-D-aspartate (nonmetabolizable glutamate analog) uptake ruled out the possibility that the decrease was a consequence of altered metabolism. However, PMA did not affect Na+-dependent [3H]-glycine transport, indicating the absence of a nonspecific change in the electrochemical gradients. The PMA effect on glutamate uptake was evidenced by partial blocking with a specific PKC inhibitor, bisindolymaleimide II (Bis II). Activation of PKC did not change the Km, but the Vmax was significantly reduced. Image analysis of Müller cells with biotinylated cell membranes immunolabeled with GLAST shows a reduction of GLAST in the plasma membrane. In conclusion, these data show that rat Müller cells in primary cultures express GLAST and that PKC activation affects GLAST transport activity by decreasing cell surface expression.
Contrast encoding in retinal bipolar cells: Current vs. voltage
- WALLACE B. THORESON, DWIGHT A. BURKHARDT
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- 13 March 2003, pp. 19-28
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To investigate the influence of voltage-sensitive conductances in shaping light-evoked responses of retinal bipolar cells, whole-cell recordings were made in the slice preparation of the tiger salamander, Ambystoma tigrinum. To study contrast encoding, the retina was stimulated with 0.5-s steps of negative and positive contrasts of variable magnitude. In the main, responses recorded under voltage- and current-clamp modes were remarkably similar. In general agreement with past results in the intact retina, the contrast/response curves were relatively steep for small contrasts, thus showing high contrast gain; the dynamic range was narrow, and responses tended to saturate at relatively small contrasts. For ON and OFF cells, linear regression analysis showed that the current response accounted for 83–93% of the variance of the voltage response. Analysis of specific parameters of the contrast/response curve showed that contrast gain was marginally higher for voltage than current in three of four cases, while no significant differences were found for half-maximal contrast (C50), dynamic range, or contrast dominance. In sum, the overall similarity between current and voltage responses indicates that voltage-sensitive conductances do not play a major role in determining the shape of the bipolar cell's contrast response in the light-adapted retina. The salient characteristics of the contrast response of bipolars apparently arise between the level of the cone voltage response and the postsynaptic current of bipolar cells, via the transformation between cone voltage and transmitter release and/or via the interaction between the neurotransmitter glutamate and its postsynaptic receptors on bipolar cells.
Morphology and spectral absorption characteristics of retinal photoreceptors in the southern hemisphere lamprey (Geotria australis)
- SHAUN P. COLLIN, NATHAN S. HART, JULIA SHAND, IAN C. POTTER
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- 26 June 2003, pp. 119-130
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The morphology and spectral absorption characteristics of the retinal photoreceptors in the southern hemisphere lamprey Geotria australis (Agnatha) were studied using light and electron microscopy and microspectrophotometry. The retinae of both downstream and upstream migrants of Geotria contained two types of cone photoreceptor and one type of rod photoreceptor. Visual pigments contained in the outer segments of these three photoreceptor types had absorbance spectra typical of porphyropsins and with wavelengths of maximum absorbance (downstream/ upstream) at 610/616 nm (long-wavelength-sensitive cone, LWS), 515/515 nm (medium-wavelength-sensitive cone, MWS), and 506/500 nm (medium-wavelength-sensitive rod). A “yellow” photostable pigment was present in the myoid region of all three types of photoreceptor in the downstream migrant. The same short-wavelength-absorbing pigment, which prevents photostimulation of the beta band of the visual pigment in the outer segment, was present in the rods and LWS cones of the upstream migrant, but was replaced by a large transparent ellipsosome in the MWS cones. Using microspectrophotometric and anatomical data, the quantal spectral sensitivity of each photoreceptor type was calculated. Our results provide the first evidence of a jawless vertebrate, represented today solely by the lampreys and hagfishes, with two morphologically and physiologically distinct types of cone photoreceptors, in addition to a rod-like photoreceptor containing a colored filter (a cone-like characteristic). In contrast, all other lampreys studied thus far have either (1) one type of cone and one type of rod, or (2) a single type of rod-like photoreceptor.
Two neuropharmacological types of rabbit ON-alpha ganglion cells express GABAC receptors
- THOMAS C. ROTOLO, RAMON F. DACHEUX
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- 18 November 2003, pp. 373-384
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The major inhibitory neurotransmitters GABA and glycine provide the bulk of input to large-field ganglion cells in the retina. Whole-cell patch-clamp recordings were used to characterize the glycine- and GABA-activated currents for morphologically identified ON-α ganglion cells in the rabbit retina. Cells identified as ON-α cells by light evoked currents were intracellularly stained and examined by light microscopy which revealed dendritic stratification in the vitreal half of the inner plexiform layer and confirmed their physiological identity. All Ca2+-mediated synaptic influences were abolished with Co2+, revealing two types of ON-α cell characterized by their different inhibitory current profiles. One group exhibited larger glycine- than GABA-activated currents, while the other group had larger GABA- than glycine-activated currents. Both cell types demonstrated strychnine-sensitive glycine-activated currents and bicuculline-sensitive GABAA-activated currents. Surprisingly, both cell types expressed functional GABAC receptors demonstrated by their sensitivity to TPMPA. In addition, the cells with larger glycine-activated currents also possessed GABAB receptors, whereas those with larger GABA-activated currents did not. Immunocytochemical experiments confirmed the presence of glycine, GABAA, and GABAC receptor subunits on all physiologically identified ON-α ganglion cells in this study. In addition, the GABAB receptor immunolabeled puncta were present on the cells with larger glycine-activated currents, but not on the cells with the larger GABA-activated currents. In conclusion, the presence of different functional GABA and glycine receptors determined physiologically correlated well with the specific GABA and glycine receptor immunolabeling for two neuropharmacological types of rabbit ON-α ganglion cells.
Desensitization of the photoresponse in Limulus ventral photoreceptors by protein kinase C precedes rhabdomere disorganization and endocytosis
- ALAIN DABDOUB, ROBERT N. JINKS, YOUJUN WANG, BARBARA-ANNE BATTELLE, RICHARD PAYNE
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- 23 September 2003, pp. 241-248
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Limulus photoreceptors utilize the phosphoinositide pathway to generate light-induced single photon events (quantum bumps) that sum to form the depolarizing receptor potential. The protein kinase C (PKC) activator, (−)-indolactam V (ILV) rapidly desensitizes the light response in Limulus ventral nerve photoreceptors. Within 10 min of extracellular application, 100 nM (−)-ILV caused a decrease in the mean amplitude of quantum bumps to 38% of control values. PKC activation by (−)-ILV also causes photosensitive membrane disorganization and endocytosis. To investigate whether this precedes desensitization of the electrical response, we fixed cells after 10-min incubation with 25 μM (−)-ILV, a concentration sufficient to cause a 1000-fold desensitization of the receptor potential. The photosensitive microvilli of these photoreceptors remained narrow, densely packed, and well organized. Increasing the incubation time to 60 min did, however, induce disorganization and swelling of the microvilli and endocytosis of the photosensitive membrane, as previously reported. Measurement of membrane capacitance did not indicate a significant reduction in membrane area accompanying desensitization by (−)-ILV. PKC-induced reduction in light sensitivity therefore precedes the detection of ultrastructural changes in the rhabdomeral membrane and is not due to a net loss of membrane.
Hyper-vision in a patient with central and paracentral vision loss reflects cortical reorganization
- CLARA CASCO, GIANLUCA CAMPANA, ALBA GRIECO, SILVANA MUSETTI, SALVATORE PERRONE
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- 22 January 2004, pp. 501-510
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SM, a 21-year-old female, presents an extensive central scotoma (30 deg) with dense absolute scotoma (visual acuity = 10/100) in the macular area (10 deg) due to Stargardt's disease. We provide behavioral evidence of cortical plastic reorganization since the patient could perform several visual tasks with her poor-vision eyes better than controls, although high spatial frequency sensitivity and visual acuity are severely impaired. Between 2.5-deg and 12-deg eccentricities, SM presented (1) normal acuity for crowded letters, provided stimulus size is above acuity thresholds for single letters; (2) a two-fold sensitivity increase (d-prime) with respect to controls in a simple search task; and (3) largely above-threshold performance in a lexical decision task carried out randomly by controls. SM's hyper-vision may reflect a long-term sensory gain specific for unimpaired low spatial-frequency mechanisms, which may result from modifications in response properties due to practice-dependent changes in excitatory/inhibitory intracortical connections.
Connexin 36 in bovine retina: Lack of phosphorylation but evidence for association with phosphorylated proteins
- ARI SITARAMAYYA, JOHN W. CRABB, DIANE F. MATESIC, ALEXANDER MARGULIS, VINITA SINGH, SADHONA PULUKURI, LOAN DANG
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- 18 November 2003, pp. 385-395
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In vertebrate retina interneuronal communication through gap junctions is involved in light adaptation and in the transfer of visual information from the rod pathway to the cone pathway. Reports over the last two decades have indicated that these gap junctions are regulated by cyclic nucleotide-dependent protein kinases suggesting that the gap junction proteins, connexins, are phosphorylated. Though all the connexins involved in light adaptation and information transfer from rod to cone pathway are not yet known, connexin 36 has been shown to be definitively involved in the latter process. We have therefore attempted to investigate the cyclic nucleotide-dependent phosphorylation of this connexin in bovine retina. We found several soluble and membrane proteins in bovine retina whose phosphorylation was regulated by cyclic nucleotides. However, no protein of about 36 kDa with cyclic nucleotide-regulated phosphorylation was found in gap junction-enriched membrane preparations. A 36-kDa phosphorylated protein was found in gap junction-enriched membranes phosphorylated in the presence of calcium. However, this protein was not immunoprecipitated by anti-connexin 36 antibodies indicating that it was not connexin 36 in spite of its similarity in molecular weight. Immunoprecipitation did reveal phosphorylated proteins coimmunoprecipitated with connexin 36. Two of these proteins were identified as beta and alpha tubulin subunits. Though cyclic GMP and calcium did not greatly influence the association of these proteins with connexin 36, the results suggest the possibility of connexin 36 associating with other proteins. Together, these observations indicate that interneuronal communication at gap junctions made by connexin 36 may not be regulated by direct phosphorylation of connexin 36, but possibly by phosphorylation of associated proteins.