Research Article
Distribution of GABA-like immunoreactive neurons and fibers in the central visual nuclei and retina of frog, Rana pipiens
- ZHENG LI, KATHERINE V. FITE
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- 01 November 1998, pp. 995-1006
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Immunocytochemistry was used to study the distribution of gamma-aminobutyric acid (GABA) throughout the central visual nuclei and retina in Rana pipiens. In the retina, GABA immunoreactivity (both somata and fibers) was observed in all layers except the outer nuclear layer (ONL). Contrary to earlier reports, about 30% of total neurons within ganglion cell layer (GCL) expressed GABA immunoreactivity. Double-labeling studies indicated that about half of the GABA-containing perikarya in the GCL were retinal ganglion cells (RGCs). In the diencephalon, intensely labeled GABA-immunoreactive neurons and nerve fibers were observed within the neuropil of Bellonci (nB) and corpus geniculatum (CG), while only immunoreactive puncta were found in the rostral visual nucleus (RVN). In the pretectal region, the posterior thalamic nucleus (nPT) contained the most intensely labeled GABA immunoreactive perikarya and nerve fibers in the entire brain. Lightly immunoreactive perikarya were also found in the large-celled nucleus lentiformis mesencephali (nLM), as well as in the pretectal gray, which contains neurons postsynaptic to the retinal terminal zones within nLM. In the optic tectum (OT), both immunoreactive perikarya and fibers were found within superficial layers 8 and 9, whereas only densely packed immunoreactive perikarya were evident in the deep tectal layers (i.e. 2, 4, 6). The nucleus of the basal optic root (nBOR) contained a small number of lightly labeled GABA-immunoreactive perikarya, mostly located in the dorsal half of the nucleus. A large number of perikarya within the nucleus isthmi (NI) were also immunostained.
Cytochrome-oxidase blobs and intrinsic horizontal connections of layer 2/3 pyramidal neurons in primate V1
- NEUSA H. YABUTA, EDWARD M. CALLAWAY
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- 01 November 1998, pp. 1007-1027
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Pyramidal neurons in superficial layers of cerebral cortex have extensive horizontal axons that provide a substrate for lateral interactions across cortical columns. These connections are believed to link functionally similar regions, as suggested by the observation that cytochrome-oxidase blobs in the monkey primary visual cortex (V1) are preferentially connected to blobs and interblobs to interblobs. To better understand the precise relationship between horizontal connections and blobs, we intracellularly labeled 20 layer 2/3 pyramidal neurons in tangential living brain slices from V1 of macaque monkeys. The locations of each cell body and the cell's synaptic boutons relative to blobs were quantitatively analyzed. We found evidence for two cell types located at characteristic distances from blob centers: (1) neurons lacking long-distance, clustered axons (somata 130–200 μm from blob centers) and (2) cells with clustered, long-distance axon collaterals (somata <130 μm or >200 μm from blob centers). For all cells, synaptic boutons close to the cell body were located at similar distances from blob centers as the cell body. The majority of boutons from cells lacking distal axon clusters were close to their cell bodies. Cells located more than 200 μm from blob centers were in interblobs and had long-distance clustered axon collaterals selectively targeting distant interblob regions. Cells located less than 130 μm from blob centers were found within both blobs and interblobs, but many were close to traditionally defined borders. The distant synaptic boutons from these cells were generally located relatively near to blob centers, but the neurons closest to blob centers had synaptic boutons closer to blob centers than those farther away. There was not a sharp transition that would suggest specificity for blobs and interblobs as discrete, binary entities. Instead they appear to be extremes along a continuum. These observations have important implications for the function of lateral interactions within V1.
Cone contributions to the photopic spectral sensitivity of the zebrafish ERG
- ALAN HUGHES, SHANNON SASZIK, JOSEPH BILOTTA, PAUL J. DEMARCO, WARREN F. PATTERSON
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- 01 November 1998, pp. 1029-1037
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Microspectrophotometry studies show that zebrafish (Danio rerio) possess four cone photopigments. The purpose of this study was to determine the cone contributions to the zebrafish photopic increment threshold spectral-sensitivity function. Electroretinogram (ERG) b-wave responses to monochromatic lights presented on a broadband or chromatic background were obtained. It was found that under the broadband background condition, the zebrafish spectral-sensitivity function showed several peaks that were narrower in sensitivity compared to the cone spectra. The spectral-sensitivity function was modeled with L − M and M − S opponent interactions and nonopponent S- and U-cone mechanisms. Using chromatic adaptation designed to suppress the contribution of the S-cones, a strong U-cone contribution to the spectral-sensitivity function was revealed, and the contributions of the S-cones to the M − S mechanism were reduced. These results show that the b-wave component of the ERG receives input from all four cone types and appears to reflect color opponent mechanisms. Thus, zebrafish may possess the fundamental properties necessary for color vision.
Inhibition of the calcineurin-like protein phosphatase activity in Limulus ventral eye photoreceptor cells alters the characteristics of the spontaneous quantal bumps and the light-mediated inward currents, and enhances arrestin phosphorylation
- LEONARD KASS, DORETTE Z. ELLIS, JANICE PELLETIER, NATHAN E. TABLEMAN, SAMUEL C. EDWARDS
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- 01 November 1998, pp. 1039-1049
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Changes in intracellular calcium are involved in phototransduction processes in both vertebrate and invertebrate photoreceptors. During this phototransduction process in the Limulus ventral eye, there is a biochemical change in the protein phosphatase, calcineurin, such that it becomes capable of activation by calcium and calmodulin. Here we show that the calcium/calmodulin-dependent calcineurin-like activity in light-adapted ventral eye was completely inhibited by the CaN autoinhibitory peptide, CaN A457–482 and the Merck analog of the membrane-permeable, immunosuppressant drug, FK 506, L-683, 590, but not an inactive analogue, L-685, 818. Whole-cell, voltage-clamp recordings of spontaneous quantal bump activity present in dark-adapted photoreceptors injected with either CaN A457–482 (500 μM) or superfused with L-683, 590 (20 μM) or L-685, 818 revealed that both CaN A457–482 and L-683, 590, but not L-685, 818, caused rapid decreases in quantal bump amplitude, rise time and fall time, resulting in smaller, sharper bumps. This was correlated with enhanced phosphorylation of arrestin in light-adapted ventral eye photoreceptors exposed to L-683, 590 or less reliably okadaic acid. Both CaN A457–482 and L-683, 590 markedly affected the light-stimulated inward currents recorded from light-adapted ventral photoreceptors, causing a “terracing” of the inward current, and an intensity-dependent delay in the time required to reach peak amplitude. Consequently, inhibition of calcineurin markedly affects two major rhodopsin-dependent electrophysiological processes, and implicates CaN as an integral component in the phototransduction cascade.
Rapid calcium-current kinetics in synaptic terminals of goldfish retinal bipolar neurons
- STEVEN MENNERICK, GARY MATTHEWS
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- 01 November 1998, pp. 1051-1056
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Onset and offset of calcium current in response to short, depolarizing voltage pulses were studied in giant synaptic terminals of goldfish bipolar neurons. Tail-current decays were extremely rapid (80 μs at −70 mV), and exponentially slowed at more positive repolarization potentials. The amplitude of tail current following voltage pulses varied with the pulse amplitude, according to a Bolzmann distribution with a V1/2 of −27.6 mV and a slope factor of 13.8 mV. When interpreted with a Hodgkin-Huxley model, calcium-current onset was best described by m2 kinetics and a time constant (τm) of 0.62 ms at −10 mV. The kinetics of calcium-current onset and offset are at least two- to threefold faster than those described in other native cells. Combined with other recent data, the results suggest that the rapid kinetics may participate in a fast signaling mode in the goldfish ON-center pathway.
A comparison of the inhibitory actions of glycine and GABA on acetylcholine release from the rabbit retina
- DAVID M. LINN
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- 01 November 1998, pp. 1057-1065
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The inhibition of [3H]acetylcholine (ACh) release from cholinergic amacrine cells by glycine and GABA was studied using an in vivo eyecup preparation in anesthetized rabbits. Glycine (1 mM) had no effect on basal ACh release, but completely blocked the light-evoked release of ACh. Glycine also blocked the strong potentiating effects of picrotoxin (20 μM) normally observed on basal and light-evoked release. Strychnine (20 μM) increased basal release, albeit less than picrotoxin, but partially inhibited and altered the shape of light-evoked responses. Co-perfusion of picrotoxin and strychnine after strychnine application resulted in a larger additional basal increase. However, light-evoked responses were not restored to a control shape and magnitude, or to potentiated levels as with picrotoxin alone, but remained altered and partially inhibited. These results support the concept of a sustained GABA-mediated inhibition of the cholinergic pathway in the intact retina. In contrast, glycine-mediated inhibition of the cholinergic pathway differs, with the present results indicating a significantly smaller sustained inhibition of basal release and a temporal inhibition of light-evoked release. The lack of effect of any of these compounds on kainate-evoked responses indicates that these effects are predominately indirect, possibly on the presynaptic bipolar cell.
Does rod phototransduction involve the delayed transition of activated rhodopsin to a second, more active catalytic state?
- DAVID R. PEPPERBERG
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- 01 November 1998, pp. 1067-1078
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Recovery kinetics of the saturating photocurrent response in amphibian rods suggest regulation of the visual signal by a first-order deactivation reaction with an exponential time constant (τc) of about 2 s. The original hypothesis that τc represents the lifetime of activated rhodopsin (R*) in a single-step deactivation appears at odds with several recent findings, for example, that Ca2+, a known regulator of the enzymatic phosphorylation of R*, does not regulate the value of τc. A recently proposed alternative hypothesis, that τc is the lifetime of activated transducin and that the R* lifetime is relatively short (∼0.4 s), appears consistent with the Ca2+ data but is difficult to reconcile with a high specific catalytic activity of R*. The present theoretical study proposes a rate-equation model of R* activation and deactivation in amphibian rods that is generally consistent with observed properties of the τc-associated reaction and the action of Ca2+ as well as with the stereotyped nature of the single-photon response. The model is developed by considering the effect of background light on a time-dependent variable, Reff*, defined as the effective total level of R* activity. Central starting assumptions are that Ca2+ reduction mediates the effect of background light on Reff*(t) and that background desensitization of the photocurrent flash response derives from this action of Ca2+. Construction of the model is guided by criteria based on previous experimental findings. Among these are the approximate constancy of background desensitization expressed at near-peak and later times in the flash response, and the large (∼10-fold) dynamic range of this desensitization. The proposed model hypothesizes that an event regulated by Ca2+ feedback causes activated rhodopsin to become susceptible to a two-phase, stochastic deactivation process, the second phase of which is characterized by τc. A central prediction of the model is the regulated transition of flash-activated R* to “R**”, a state exhibiting greatly increased catalytic activity.
Stimulus features eliciting visual responses from neurons in the nucleus lentiformis mesencephali in pigeons
- YU-XI FU, QUAN XIAO, HONG-FENG GAO, SHU-RONG WANG
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- 01 November 1998, pp. 1079-1087
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The purpose of the present study was to find out what particular stimulus features, in addition to the direction and velocity of motion, specifically activate neurons in the nucleus lentiformis mesencephali (nLM) in pigeons. Visual responses of 60 nLM cells to a variety of computer-generated stimuli were extracellularly recorded and quantitatively analyzed. Ten recording sites were histologically verified to be localized within nLM with cobalt sulfide markings. It was shown that the pigeon nLM cells were specifically sensitive to the leading edge moving at the optimal velocity in the preferred direction through their excitatory receptive fields (ERFs). Generally speaking, nLM cells preferred black edges to white ones. However, this preference cannot be explained by OFF-responses to a light spot. The edge sharpness was also an essential factor influencing the responsive strength, with blurred edges producing little or no visual responses at all. These neurons vigorously responded to black edge orientated perpendicular to, and moved in, the preferred direction; the magnitude of visual responses was reduced with changing orientation. The spatial summation occurred in all neurons tested, characterized by the finding that neuronal firings increased as the leading edge was lengthened until saturation was reached. On the other hand, it appeared that nLM neurons could not detect any differences in the shape and area of stimuli with an identical edge. These data suggested that feature extraction characteristics of nLM neurons may be specialized for detecting optokinetic stimuli, but not for realizing pattern recognition. This seems to be at least one of the reasons why large-field gratings or random-dot patterns have been used to study visual responses of accessory optic neurons and optokinetic nystagmus, because many high-contrast edges in these stimuli can activate a neuron to periodically discharge, or groups of neurons to simultaneously fire to elicit optokinetic reflex.
Opiate and N-methyl-D-aspartate receptors in form-deprivation myopia
- ANDY J. FISCHER, RUTH L.P. SELTNER, WILLIAM K. STELL
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- 01 November 1998, pp. 1089-1096
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Pharmacological studies have implicated retinal opiate pathways in the visual regulation of ocular growth. However, the effects of opiate receptor subtype-specific compounds on form-deprivation myopia (FDM) are inconsistent (Seltner et al., 1997), and may be mediated by non-opiate receptors. The purpose of this study was to test whether opiate receptor-inactive (D-) enantiomers elicit the same FDM-suppressing effect as their opiate receptor-active (L-) counterparts. Since some opiates are thought to act at NMDA receptors, we also tested whether NMDA receptor agonists and antagonists influence ocular growth or FDM. We found that both L- and D- enantiomers of morphine-like compounds (dextrorphanol and levorphanol, and D- and L-naloxone) were equally effective in blocking FDM. The NMDA receptor antagonists dextromethorphan, MK801, and AP5 also suppressed FDM. A single toxic dose of NMDA, that destroys many subtypes of amacrine cells (including those that synthesize the opioid peptide enkephalin), induced myopia and ocular enlargement in ungoggled eyes, and eliminated the ability of form-deprivation to enhance ocular growth. The NR-1 subunit of the NMDA receptor was localized to a narrowly stratified, intense stratum at approximately 50% depth in the inner plexiform layer, diffusely throughout the proximal inner plexiform layer, and to many somata in the amacrine and ganglion cell layers. These observations suggest that most effects of opiate receptor ligands on FDM in the chick are mediated by non-opiate receptors, which are likely to include NMDA receptors. NMDA as an excitotoxin transiently enhances ocular growth, but thereafter disables retinal mechanisms that promote emmetropization and FDM. These observations are consistent with a prominent role for pathways utilizing NMDA receptors in FDM and ocular growth-control.
Monocular enucleation prevents retinal ganglion-cell loss following neonatal visual cortex damage in cats
- KURT R. ILLIG, VON R. KING, PETER D. SPEAR
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- 01 November 1998, pp. 1097-1105
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Damage to primary visual cortex (VC) in young cats leads to severe retrograde degeneration of the dorsal lateral geniculate nucleus (dLGN) and selective transneuronal retrograde degeneration of a class of retinal ganglion cells (RGCs) that have a medium-size soma. Previous studies have shown that “programmed” RGC death associated with normal development in one eye can be attenuated by removal of the other eye, suggesting that binocular interactions can influence developmental RGC death. The present study investigated whether removal of one eye also attenuates the ganglion cell loss that accompanies an early VC lesion. Five one-week-old cats received a unilateral VC lesion (areas 17, 18, and 19), and three of these cats also underwent monocular enucleation at the same time. Two normal control animals also were examined. RGC measurements were made from flat-mounted retinae when the animals were 5 weeks old. Sampling was restricted to a retinal area corresponding to the retinotopic representation included in the VC lesion. Results indicate that there is a marked loss of medium-size RGCs in the hemiretinae projecting to the damaged hemisphere in cats that received a VC lesion alone. However, there is no such loss in VC-lesion animals that also have a monocular enucleation. These results indicate that the transneuronal RGC loss that occurs after an early visual cortex lesion can be influenced by binocular interactions.
Neural correlates of boundary perception
- AUDIE G. LEVENTHAL, YONGCHANG WANG, MATTHEW T. SCHMOLESKY, YIFENG ZHOU
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- 01 November 1998, pp. 1107-1118
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The responses of neurons in areas V1 (17) and V2 (18) of anesthetized and paralyzed rhesus monkeys and cats were recorded while presenting a set of computer-generated visual stimuli that varied in pattern, texture, luminance, and contrast. We find that a class of extrastriate cortical cells in cats and monkeys can signal the presence of boundaries regardless of the cue or cues that define the boundaries. These cue-invariant (CI) cells were rare in area V1 but easily found in V2. CI cortical cells responded more strongly to more salient boundaries regardless of the cue defining the boundaries. Many CI cortical cells responded to illusory contours and exhibited the same degree of orientation and direction selectivity when tested with boundaries defined by different cues. These cells have significant computational power inherent in their receptive fields since they were able to generalize across stimuli and integrate multiple cues simultaneously in order to signal boundaries. Cells in higher order cortical areas such as MT (Albright, 1992), MST (Geesaman & Anderson, 1996), and IT (Sary et al., 1993) have previously been reported to respond in a cue invariant fashion. The present results suggest that the ability to respond to boundaries in a cue-invariant manner originates at relatively early stages of cortical processing.
Complementary roles of two excitatory pathways in retinal directional selectivity
- NORBERTO M. GRZYWACZ, DAVID K. MERWINE, FRANKLIN R. AMTHOR
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- 01 November 1998, pp. 1119-1127
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The two major excitatory synapses onto ON–OFF directionally selective (DS) ganglion cells of the rabbit retina appear to be nicotinic cholinergic and NMDA glutamatergic. Blockade of either of these synapses with antagonists does not eliminate directional selectivity. This suggests that these synapses may have complementary roles in the computation of the direction of motion. To test this hypothesis, quantitative features of the DS cell excitatory pathways were determined by collecting responses, under nicotinic and/or NMDA blockade, to a sweeping bar, hyperacute apparent motions, or a drifting sinusoidal grating. Sweeping bar responses were reduced, but directional selectivity not eliminated, by blockade of either excitatory path, as previously shown (Cohen & Miller, 1995; Kittila & Massey, 1997). However, residual responses under combined blockades were not statistically significantly DS. NMDA blockade reduced responses more than nicotinic blockade for each protocol, and shifted hyperacute motion thresholds to higher values. This supported the notion that glutamate provides the main excitatory drive to DS cells, that is, the one responsible for contrast sensitivity. In turn, nicotinic, but not NMDA blockade eliminated directional selectivity to a drifting low spatial-frequency sinusoidal grating in these cells. This suggested that acetylcholine (ACh) is the main excitatory input with regards to directional selectivity for some textured stimuli, that is, those with multiple peaks in their spatial luminance profile. Moreover, nicotinic blockade raised the low temporal-frequency cutoff of the grating responses, consistent with the proposal that preferred-direction facilitation, which is temporally sustained, is dependent on the cholinergic input. These different properties of the NMDA and nicotinic pathways are consistent with a recently proposed two-asymmetric-pathways model of directional selectivity.
Non-monotonic contrast behavior in directionally selective ganglion cells and evidence for its dependence on their GABAergic input
- DAVID K. MERWINE, NORBERTO M. GRZYWACZ, DARREL S. TJEPKES, FRANKLIN R. AMTHOR
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- 01 November 1998, pp. 1129-1136
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We serendipitously discovered that the preferred-direction responses of ON–OFF directionally selective (DS) ganglion cells in the rabbit retina fall as a function of contrast when the contrast of a moving bar exceeds about 100%. Null-direction responses did not fall for contrasts up to 400%. Because the non-monotonic (rise-then-fall) behavior as a function of contrast occurred only for preferred-direction responses, it must depend on the mechanism of directional selectivity. It became thus of interest to investigate how this non-monotonicity depends on the major synapses involved in directional selectivity. Blockades of nicotinic acetylcholine (ACh) and NMDA glutamate receptors reduced responses without eliminating preferred-response non-monotonicity. Blocking GABAergic inhibition, however, did eliminate non-monotonicity. These results pose a difficult puzzle, since in the accompanying paper (Grzywacz et al., 1998), we showed that residual responses under combined nicotinic and NMDA blockades are not statistically significantly directionally selective. How is it possible that null-direction GABAergic inhibition affects non-nicotinic-non-NMDA residual responses without generating directional selectivity? This may happen if there exists an asymmetric GABAergic input to distal dendrites of the DS cell while the excitatory, non-nicotinic-non-NMDA input is to proximal dendrites. In support of this hypothesis, bath-applied GABA reduces responses to exogenous ACh under synaptic block, providing for the first time in the rabbit's retina, direct evidence of GABA receptors on DS cells.
Cloning and functional expression of a novel gap junction channel from the retina of Danio aquipinnatus
- T.L.E. WAGNER, E.C. BEYER, D.G. McMAHON
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- 01 November 1998, pp. 1137-1144
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Electrical synapses, or gap junctions, are widely distributed in the vertebrate retina and are thought to play critical roles in the transmission and coding of visual signals. To investigate the molecular basis of this form of neural communication in the retina, we have isolated, characterized, and functionally expressed a cDNA for a gap junction channel derived from the retina of the teleost fish Danio aquipinnatus (giant danio). The cDNA contained an open reading frame of 1146 nucleotides encoding a connexin with a predicted molecular mass of 43.3 kDa which shared extensive identity with Rattus norvegicus Cx43 (78%). This protein (DACX43) contained several consensus phosphorylation sequences in the c-terminal region, some of which are conserved among Cx43 orthologs. RNA blot hybridization revealed that DACX43 was expressed in the brain as well as in the retina. In addition, Southern analysis suggested that there are multiple copies of DACX43, or other closely related sequences, in the Danio aquipinnatus genome. When DACX43 was expressed by stable transfection in gap-junction-deficient mouse N2A neuroblastoma cells, functional gap junctions were formed as indicated by dual whole-cell recordings of electrical coupling. We conclude that DACX43 is a connexin43 ortholog, which is expressed in the retina of Danio aquipinnatus, and when translated is able to form functional gap junction channels.
Functional properties of retinal ganglion cells during optic nerve regeneration in the goldfish
- D.-J. OH, D.P.M. NORTHMORE
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- 01 November 1998, pp. 1145-1155
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After being severed, optic axons in goldfish regenerate and eventually restore the retinotectal map; refinement of the map depends upon impulse activity generated by the ganglion cells. Because little is known about the changes in activity and receptive-field properties of ganglion cells during regeneration, we made extracellular recordings from them in the intact eye up to 95 days after sectioning their axons in the optic tract. Their receptive fields were classified as OFF-, ON–OFF-, or ON-centers, and their axonal conduction velocities measured by antidromic activation. The rate of encountering single units dropped drastically at 4–8 days postsection when only a few OFF-center units could be recorded, recovering to normal between 42 and 63 days. Receptive-field centers were normal in size, except for the few OFF-centers at 4–8 days which were abnormally large. Maintained discharge rates of all types were depressed up to 42 days, but ON–OFF-center units were more spontaneously active than normal around 42 days. Light-evoked responses in OFF-center units were subnormal at 4–8 days, becoming supernormal at 16 days and normal thereafter. ON–OFF- and ON-center units started to regain responsiveness at 16 days, and became supernormal at 42 days, before returning to normal. Conduction velocities of all fiber groups dropped to a minimum at 8 days, the fastest being affected most. There was a gradual recovery to normal conduction velocity by 63 days. The conduction latencies of OFF- and ON–OFF-center units recovered to normal by 42 days, and ON-center units by 63 days. Recovery of ganglion cell responsiveness correlates with functional recovery in the retinotectal system: OFF-center units recover light-evoked responses at about the time OFF activity first reappears in the tectum. ON- and ON–OFF-center units recover later, exhibiting supernormal spiking activity around the time that ON responses reappear in the tectum.
A phenomenological model of visually evoked spike trains in cat geniculate nonlagged X-cells
- NICOLAS GAZÈRES, LYLE J. BORG-GRAHAM, YVES FRÉGNAC
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- 15 May 2002, pp. 1157-1174
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The visual information that first-order cortical cells receive is contained in the visually evoked spike trains of geniculate relay cells. To address functional issues such as the ON/OFF structure of visual cortical receptive fields with modelling studies, a geniculate cell model is needed where the spatial and temporal characteristics of the visual response are described quantitatively. We propose a model simulating the spike trains produced by cat geniculate nonlagged X-cells, based on a review of the electrophysiological literature. The level of description chosen is phenomenological, fitting the dynamics and amplitude of phasic and tonic responses, center/surround antagonism, surround excitatory responses, and the statistical properties of both spontaneous and visually evoked spike trains. The model, which has been constrained so as to reproduce the responses to centered light spots of expanding size and optimal light and dark annuli, predicts responses to thin and large bars flashed in various positions of the receptive field. The switching gamma renewal process method has been introduced for modelling spontaneous and visually evoked spike trains within the same mathematical framework. The statistical structure of the spike process is assumed to be more regular during phasic than tonic visual responses. On the whole, this model generates more realistic geniculate input to cortex than the currently used retinal models.
Identification and distribution of photoreceptor subtypes in the neotenic tiger salamander retina
- DAVID M. SHERRY, DAI D. BUI, WILLEM J. DEGRIP
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- 01 November 1998, pp. 1175-1187
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The neotenic tiger salamander retina is a major model system for the study of retinal physiology and circuitry, yet there are unresolved issues regarding the organization of the photoreceptors and the photoreceptor mosaic. The rod and cone subtypes in the salamander retina were identified using a combination of morphological and immunocytochemical markers for specific rod and cone opsin epitopes. Because the visual pigment mechanisms present in the tiger salamander retina are well characterized and the antibodies employed in these studies are specific for particular rod and cone opsin epitopes, we also were able to identify the spectral class of the various rod and cone subtypes. Two classes of rods corresponding to the “red” and “green” rods previously reported in amphibian retinas were identified. In serial semithin section analyses, rods and cones comprised 62.4 ± 1.4% and 37.6 ± 1.4% of all photoreceptors, respectively. One rod type comprising 98.0 ± 0.7% of all rods showed the immunological and morphological characteristics of “red” rods, which are maximally sensitive to middle wavelengths. The second rod subtype comprised 2.0 ± 0.7% of all rods and possessed the immunological and morphological characteristics of “green” rods, which are maximally sensitive to short wavelengths. By morphology four cone types were identified, showing three distinct immunological signatures. Most cones (84.8 ± 1.5% of all cones), including most large single cones, the accessory and principal members of the double cone, and some small single cones, showed immunolabeling by antisera that recognize long wavelength-sensitive cone opsins. A subpopulation of small single cones (8.4 ± 1.7% of all cones) showed immunolabeling for short wavelength-sensitive cone opsin. A separate subpopulation of single cones which included both large and small types (6.8 ± 1.4% of all cones) was identified as the UV-Cone population and showed immunolabeling by antibodies that recognize rod opsin epitopes. Analysis of flatmounted retinas yielded similar results. All photoreceptor types appeared to be distributed in all retinal regions. There was no obvious crystalline organization of the various photoreceptor subtypes in the photoreceptor mosaic.
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Perfusion system components release agents that distort functional properties of rod cyclic nucleotide-gated ion channels
- JENNIFER I. CRARY, SHARONA E. GORDON, ANITA L. ZIMMERMAN
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- 01 November 1998, pp. 1189-1193
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In switching from studying native cyclic nucleotide-gated (CNG) ion channels in rod cells to studying the corresponding cloned channels expressed in Xenopus oocytes, we changed our perfusion system to a more efficient one. This change involved replacing culture flasks and a small plexiglass/glass chamber with plastic syringes, metal needles, and plastic petri dishes. We now report that these new perfusion system components release agents that distort or obscure measured functional properties of rod CNG channels. The magnitude and time course of appearance of the artifacts vary widely among individual components (e.g. from syringe to syringe). The effects most resemble voltage-dependent block of the channels, giving a decrease in current at positive potentials, and producing distortions of the kinetics and voltage dependence of channel activation.