Research Article
Effect of sensory disuse on geniculate afferents to cat visual cortex
- ANTONELLA ANTONINI, MICHAEL P. STRYKER
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- 01 March 1998, pp. 401-409
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In the kitten, as little as a week of monocular lid suture during early life causes a remarkable remodeling of the geniculocortical projections serving the deprived eye (Antonini & Stryker, 1993a, 1996). While the physiological effects of monocular deprivation have been shown to be due to competitive interactions between the projections serving the two eyes, it is not known whether these morphological changes are due to competitive interactions or to sensory disuse. We addressed this question by analyzing the morphology of geniculocortical arbors in kittens deprived of patterned vision by binocular lid suture for 1 week or 2 weeks ending at 6 weeks of age. Such deprivation would be expected to affect the afferents serving the two eyes equally, giving neither eye a competitive advantage. The arbors were anterogradely filled with Phaseolus lectin iontophoretically injected into lamina A of the lateral geniculate nucleus. The lectin was visualized immunohistochemically, and single geniculocortical arbors were serially reconstructed in three dimensions. Arbors reconstructed in binocularly deprived animals were compared with arbors serving the deprived and nondeprived eye in animals monocularly deprived by lid suture of one eye for a week and with arbors obtained in age-matched normal controls. Geniculocortical arbors in binocularly deprived animals did not suffer the drastic remodeling of the deprived arbors in monocularly deprived animals. Indeed, arbors in binocularly deprived animals were indistinguishable from arbors in normal kittens or nondeprived arbors in short-term monocularly deprived animals. These results support the notion that competitive mechanisms rather than sensory disuse are responsible for gross morphological remodeling of geniculocortical arbors.
Centrifugal innervation modulates visual activity of tectal cells in pigeons
- JIAN-LI LI, QUAN XIAO, YU-XI FU, SHU-RONG WANG
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- 01 March 1998, pp. 411-415
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Centrifugal modulation of visual responsiveness of tectal cells by the isthmo-optic nucleus (ION) through the retina was studied in homing pigeons. Visual activity evoked by computer-generated stimuli was reduced by an average of 59% in tectal cells whose receptive fields (RFs) either overlapped with, or were close to, those of isthmo-optic cells whose activity was blocked by the injection of lidocaine through micropipettes. Activity usually recovered to 87% of pre-drug controls in 8–17 min (average 12.3 min) after stopping lidocaine injections. Those tectal cells whose RFs were far from those of ION cells did not show clear-cut changes in their visual responsiveness to isthmo-optic lidocaine application. The spatial relationship between receptive fields of tectal and isthmo-optic cells, saline controls, as well as the specificity, reproducibility and reversibility of effects of ION-injected lidocaine on tectal activity, show that this chemical action is pharmacological, not toxicological. Neuronal circuitry underlying centrifugal modulation of tectal activity by isthmo-optic cells is discussed.
Long-range competition among the neurons projecting centrifugally to the quail retina
- HIROYUKI UCHIYAMA, SHINJIRO NAKAMURA, TAKAHIKO IMAZONO
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- 01 March 1998, pp. 417-423
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Birds have a well-developed centrifugal pathway from the isthmo-optic nucleus to the retina. In the present study, receptive-field properties of the isthmo-optic (IO) neurons and suppressive effect of remote stimuli far beyond the “classical” receptive fields were examined electrophysiologically in the Japanese quail. Receptive fields emitting more than half the maximal ON–OFF response to a small spot of light measured 4.3 ± 1.9 deg (n = 37) in diameter. A stationary spot of light was presented at a remote point (35–76 deg) away from the receptive-field center, besides a stimulus for the receptive-field center, with various onset time difference. The peripheral spot, when turned on 50–100 ms before the center spot, maximally suppressed the ON and OFF responses to the center spot. In most of the IO neurons examined (13 out of 15 units), even small remote stimuli (2–5 deg in diameter) significantly suppressed the ON–OFF responses to the center stimulus. The suppressive effects of remote stimuli were seen to be extended to, at least, two thirds of the entire visual field of a single eye. Such wide suppressive fields indicate that the IO neurons may compete with each other for activity in a very long-range scale. Simulation using a simple static model based on three basic principles of processing of the centrifugal visual system— topographical input, long-range competition, and local gain enhancement—suggests that the system could function as an autonomous mechanism for attentional object selection.
The intrinsic dynamics of retinal bipolar cells isolated from tiger salamander
- BU-QING MAO, PETER R. MACLEISH, JONATHAN D. VICTOR
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- 01 March 1998, pp. 425-438
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We studied how intrinsic membrane properties affect the gain and temporal pattern of response in bipolar cells dissociated from retinae of tiger salamanders. Currents specified by a pseudorandom binary sequence, an m-sequence, superimposed on various means, were injected into the cells. From the resultant membrane voltage response for each mean current, impulse responses were estimated. From each impulse response, transfer function, gain, and time constant were calculated. The bipolar cells acted as quasilinear adaptive filters whose gain and response speed are determined by the mean input current. Near resting potential, gain, and time constant were maximum. Dynamics were slow and low-pass, characterized by an approximately exponential impulse response. With depolarization, gains were reduced sharply, responses were much faster, and dynamics became band-pass, as indicated by an undershoot in the impulse response. For any given mean current, the shape of the impulse response did not depend on the amplitude of the m-sequence currents. Thus, bipolar cells behaved in a quasilinear fashion. The adaptive behavior was eliminated by blocking a potassium current, which implicates the role of a voltage-gated potassium conductance. Computer simulations on a model neuron including a delayed-rectifier reconstructed the observed behavior, and provided insight into other, less readily observable, parameters. Thus, bipolar cells, even when isolated, possess mechanisms which regulate, with unsuspected elaborateness, the sensitivities and dynamics of their responsiveness. Implications for adaptation and neuronal processing are discussed.
Distinguishing direction selectivity from orientation selectivity in the rabbit retina
- SHIGANG HE, W.R. LEVICK, D.I. VANEY
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- 01 March 1998, pp. 439-447
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Direction selectivity and orientation selectivity were examined in the direction-selective (DS) and orientation- selective (OS) ganglion cells in the rabbit retina. Spike activities were recorded in vivo using tungsten-in-glass electrodes. Three types of visual stimuli (flashing slit, moving edges behind a slit, and whole-field drifting gratings) were used to distinguish these attributes. Fourier analysis was performed on data obtained using drifting gratings as proposed by Worgotter and Eysel (1987). Results from both angular and Fourier (polar angle frequency) domains were consistent. DS cells had strong directional components and varying strength of orientational components; they also had intact inhibitory surrounds. The phase of the biased orientation did not have a consistent relationship with the preferred direction. OS cells had predominant orientational components and very weak directional components. We conclude that the orientation bias does not contribute to the generation of direction selectivity, and that the mechanism of this bias of DS cells is rather different from the mechanism that generates orientation selectivity in rabbit OS cells. There are indications that it is similar to the mechanism shown to cause orientation bias in cat concentric cells.
The role of potassium conductance in the generation of light responses in Müller cells of the turtle retina
- DAVID M. LINN, EDUARDO SOLESSIO, IDO PERLMAN, ERIC M. LASATER
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- 01 March 1998, pp. 449-458
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Müller cells are highly permeable to potassium ions and play a major role in maintaining potassium homeostasis in the vertebrate retina during light-evoked neuronal activity. Potassium fluxes across the Müller cell's membrane are believed to underlie the light-evoked responses of these cells. We studied the potassium currents of turtle Müller cells in the retinal slice and in dissociated cell preparations and their role in the genesis of the light-evoked responses of these cells. In either preparation, the I–V curve, measured under voltage-clamp conditions, consisted of inward and outward currents. A mixture of cesium ions, TEA, and 4-AP blocked the inward current but had no effect on the outward current. Extracellular cesium ions alone blocked the inward current but exerted no effect on the photoresponses. Extracellular barium ions blocked both inward and outward currents, induced substantial depolarization, and augmented the light-evoked responses, especially the OFF component. Exposing isolated Müller cells to a high potassium concentration did not cause any current or voltage responses when barium ions were present. In contrast, application of glutamate in the presence of barium ions induced a small inward current that was associated with a substantially augmented depolarizing wave relative to that observed under control conditions. This observation suggests a role for an electrogenic glutamate transporter in generating the OFF component of the turtle Müller cell photoresponse.
Ascending projections from the optic tectum in the lizard Podarcis hispanica
- ALINO MARTÍNEZ-MARCOS, CRISTIAN FONT, ENRIQUE LANUZA, FERNANDO MARTÍNEZ-GARCÍA
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- 01 March 1998, pp. 459-475
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The ascending projections of the optic tectum, including their cells of origin, have been studied in the lizard Podarcis hispanica by means of a two-step experimental procedure. First, tracers were injected in the tectum to study the anterograde labeling in the forebrain. Second, the cells of origin of these projections have been identified by analyzing the retrograde labeling after tracer injections in the thalamus, hypothalamus, and pretectum. Three main tectal ascending pathways have been described: the dorsal tecto-thalamic tract (dtt), the medial tecto-thalamic tract (mtt), and the ventral tecto-thalamic tract (vtt). The dtt originates in radial cells of layers 5 and 7 and bipolar cells of layers 8 and 10 that project to the lateral neuropile of the dorsal lateral geniculate nucleus (GLD), to the intergeniculate leaflet (IGL), and to the ventral lateral geniculate nucleus (GLV). The mtt arises from radial neurons of layers 3 and 5 and bilaterally reaches the putative reticular thalamus and its boundary with the hypothalamus, the rostral IGL, and the area triangularis (AT). The vtt is composed of fibers from ganglion and multipolar cells of the layer 7 that project bilaterally to the nucleus of the vtt, the ventrolateral thalamic nucleus, the medial posterior thalamic nucleus (MP), the nucleus rotundus (Rot), the IGL, and the cell plate of the GLD. Therefore, the GLD receives not only direct retinal afferents but also two different tectal inputs, thus constituting a convergence point in the two visual pathways to the telencephalon. Moreover, different tectal cells specifically project to the ventrolateral thalamus and to pretectal nuclei. These results are discussed from comparative and functional viewpoints.
Development of multibank rod retinae in deep-sea fishes
- ELEONORE FRÖHLICH, HANS-JOACHIM WAGNER
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- 01 March 1998, pp. 477-483
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We studied the development of multibank rod retinae by monitoring the size-related addition of new layers of rod inner and outer segments in four species of deep-sea fishes and found two different growth paradigms. In the mesopelagic Chauliodus sloani, new banks of rod inner and outer segments are added as long as the fish increases in size, as observed earlier by Locket (1980). By contrast, in three bathybenthic species (Antimora rostrata, Coryphaenoides (Coryphaenoides) guentheri, and Coryphaenoides (Nematonurus) armatus), the final complement of banks is reached when the specimens have grown to between 20 and 47% of their maximal size, suggesting that the visual system is mature only after this stage. Increase in retinal area, density of rod nuclei, and densities of rod inner and outer segments were also studied in these and additional species. Taken together with previous data on rod proliferation patterns and outer segment membrane synthesis, our findings indicate that at least in species with no continual addition of new banks, there is no major functional difference between the innermost and outermost banks of rod inner and outer segments. While Chauliodus spends all its life in the mesopelagic environment, the three bathybenthic species live in this environment during early development and descend towards greater depths only upon maturation. We speculate that this coincides with the stage when the full complement of rod banks is formed in the retina, as a possible prerequisite for a life outside the reach of sunlight.
Functional localization of soluble guanylate cyclase in turtle retina: Modulation of cGMP by nitric oxide donors
- TODD A. BLUTE, PAULA VELASCO, WILLIAM D. ELDRED
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- 01 March 1998, pp. 485-498
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The second messenger cyclic guanosine monophosphate (cGMP) plays a role in many aspects of retinal processing. cGMP-gated channels function in photoreceptors, Müller, bipolar, and ganglion cells; and cGMP can modulate gap-junction conductivity. In the inner retina, both particulate and soluble guanylate cyclases can elevate levels of cGMP. The soluble isoform of guanylate cyclase is activated by nitric oxide (NO). In turtle retina, nitric oxide synthase, the enzyme that synthesizes NO, has been previously localized in discrete amacrine cells, somata in the ganglion cell layer, and in many processes in the inner plexiform layer. However, there have been no studies localizing soluble guanylate cyclase in the turtle retina. To functionally localize soluble guanylate cyclase, we stimulated retinas with the NO donors (±)-S-nitroso-N-acetylpenicillamine or spermine (nitric oxide) adduct, and then used immunocytochemistry to localize increases in cGMP-like immunoreactivity (cGMP-LI). The cells containing soluble guanylate cyclase should show cell autonomous increases in cGMP-LI in response to stimulation with NO. NO-stimulated increases in cGMP-LI occurred in many distinct amacrine cell types, select bipolar cells, some somata in the ganglion cell layer, and in discrete bands of processes in the inner plexiform layer. The pattern of cGMP-LI demonstrated qualitative dose response differences to the NO donors. This is the first localization of soluble guanylate cyclase in specific retinal neurons in the turtle; and the first functional activation of soluble guanylate cyclase in the amacrine cells of any species. The broad neuronal distribution of NO-stimulated cGMP-LI suggests that the NO/soluble guanylate cyclase/cGMP cascade is involved at several levels of visual processing in the inner retina.
Spectral sensitivity of melatonin synthesis suppression in Xenopus eyecups
- GREGORY M. CAHILL, SANDRA E. PARSONS, JOSEPH C. BESHARSE
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- 01 March 1998, pp. 499-502
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Melatonin synthesis in retinal photoreceptors is stimulated at night by a circadian oscillator and suppressed acutely by light. To identify photoreceptor mechanisms involved in the acute suppression of melatonin synthesis, an action spectrum was measured for dark-adapted Xenopus laevis eyecups at night. Intensity–response curves at six wavelengths from 400 to 650 nm were parallel, suggesting that a single photopigment predominates in melatonin suppression. Half-saturating intensities at 400, 440, 480, and 533 nm were not significantly different from one another, at 1–2 × 108 quanta cm−2 s−1. Significantly higher intensities of 580- and 650-nm light were required for melatonin suppression. These results indicate a predominant role for the principal green-absorbing rods in acute regulation of retinal melatonin synthesis in response to light, and argue against an important role for the red-absorbing cones. Higher than expected sensitivity at short wavelengths suggests that photoreceptors sensitive to blue and/or violet light may also contribute to melatonin suppression.
PET reveals occipitotemporal pathway activation during elementary form perception in humans
- LORI L. BEASON-HELD, KEITH P. PURPURA, JOHN W. VAN METER, NINA P. AZARI, DAVID J. MANGOT, LANCE M. OPTICAN, MARC J. MENTIS, GENE E. ALEXANDER, CHERYL L. GRADY, BARRY HORWITZ, STANLEY I. RAPOPORT, MARK B. SCHAPIRO
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- 01 March 1998, pp. 503-510
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To define brain regions involved in feature extraction or elementary form perception, regional cerebral blood flow (rCBF) was measured using positron emission tomography (PET) in subjects viewing two classes of achromatic textures. Textures composed of local features (e.g. extended contours and rectangular blocks) produced activation or increased rCBF along the occipitotemporal pathway relative to textures with the same mean luminance, contrast, and spatial-frequency content but lacking organized form elements or local features. Significant activation was observed in striate, extrastriate, lingual, and fusiform cortices as well as the hippocampus and brain stem. On a scan-by-scan basis, increases in rCBF shifted from the occipitotemporal visual cortices to medial temporal (hippocampus) and frontal lobes with increased exposure to only those textures containing local features. These results suggest that local feature extraction occurs throughout the occipitotemporal (ventral) pathway during extended exposure to visually salient stimuli, and may indicate the presence of similar receptive-field mechanisms in both occipital and temporal visual areas of the human brain.
Reliable disparity estimation through selective integration
- MICHAEL S. GRAY, ALEXANDRE POUGET, RICHARD S. ZEMEL, STEVEN J. NOWLAN, TERRENCE J. SEJNOWSKI
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- 01 March 1998, pp. 511-528
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A network model of disparity estimation was developed based on disparity-selective neurons, such as those found in the early stages of processing in the visual cortex. The model accurately estimated multiple disparities in regions, which may be caused by transparency or occlusion. The selective integration of reliable local estimates enabled the network to generate accurate disparity estimates on normal and transparent random-dot stereograms. The model was consistent with human psychophysical results on the effects of spatial-frequency filtering on disparity sensitivity. The responses of neurons in macaque area V2 to random-dot stereograms are consistent with the prediction of the model that a subset of neurons responsible for disparity selection should be sensitive to disparity gradients.
The maintained discharge of neurons in the cat lateral geniculate nucleus: Spectral analysis and computational modeling
- PRATIK MUKHERJEE, EHUD KAPLAN
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- 01 March 1998, pp. 529-539
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The maintained discharge of neurons along the early visual pathway in mammals constitutes the “noise” from which the visual signal must be discriminated. The statistics of this background noise in cat retinal ganglion cells (RGCs) have been shown to conform to that of a gamma-distributed renewal process (Kuffler et al., 1957; Barlow & Levick, 1969), and power spectrum analysis reveals that this property allows for low noise levels at the temporal-frequency range (0–10 Hz) most important for visual performance (Troy & Robson, 1992). In this study, we compare the statistics of the maintained discharge of cat lateral geniculate neurons with those of its RGC input by simultaneous recordings of spikes and S-potentials in single relay cells of the cat lateral geniculate nucleus (LGN). We demonstrate that, during primarily tonic spiking activity, the LGN maintained discharge preserves the renewal process statistics of its RGC input and also generates relatively little noise at the temporal frequencies important for vision. However, during burst spiking activity, the renewal process model breaks down and increased noise is generated at 2–10 Hz. This suggests that optimization of the visual signal/noise ratio is not a prime consideration in the behavioral states associated with bursting activity in the LGN. The occurrence of burst spikes in LGN relay cells is dependent on the activity of T-type calcium channels in their plasma membranes (Jahnsen & Llinas, 1984a,b). We show that a computational model of LGN relay cells that incorporates T-channel kinetics (Mukherjee & Kaplan, 1995) can correctly simulate LGN maintained discharge statistics during both tonic and bursty firing conditions, and indicates an essential role for this ion channel in determining the dynamic noise properties of the LGN. We also use the computational model to predict how the burstiness of the LGN maintained discharge is affected by the statistics of its RGC input.
Localization and properties of voltage-gated calcium channels in cone photoreceptors of Tupaia belangeri
- W. ROWLAND TAYLOR, CATHERINE MORGANS
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- 01 March 1998, pp. 541-552
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In spiking neurons, phasic, calcium-dependent transmitter release is initiated when a presynaptic action potential activates voltage-dependent calcium channels. Vertebrate photoreceptors are nonspiking neurons that continuously release transmitter. This study uses patch-clamp recording to examine the electrophysiological properties of mammalian cones in intact retina. The cell capacitance was 10 ± 1 pF and the input resistance was 0.52 ± 0.46 G-ohms at −65 mV (31 cells). A specific membrane capacitance of 1.2 pF/cm2 was calculated. The cones did not appear to be chemically or electrically coupled. The calcium conductance averaged 3 ± 1 nS (five cells). Fifty percent of the calcium channels were active at −40 mV, and at this voltage the number of active channels changed e-fold for a 6-mV voltage change. At 25°C, the current reached a peak within about 1 ms after onset of a step to −35 mV. The calcium influx produced by depolarization activated a chloride conductance with a delay of a few milliseconds. The channels did not completely inactivate during maintained depolarization. The calcium channels were partially blocked by high concentrations of nifedipine, an L-type specific antagonist, and were recognized by an antibody raised against the L-type subunit α-1D. The immunohistochemical staining shows that the calcium channels are localized to the synaptic terminals. The immunohistochemical, physiological, and pharmacological properties indicate that the calcium channels in mammalian photoreceptors may represent a novel isoform, possibly with some homologies to the L-type class. The activation range of the channels matches the physiological operating range of photoreceptors.
Clustering of response selectivity in the medial superior temporal area of extrastriate cortex in the macaque monkey
- KENNETH H. BRITTEN
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- 01 March 1998, pp. 553-558
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Ever since being described by Mountcastle (Mountcastle, 1957), columnar organization of sensory cortical areas has provided key leverage into understanding the functional organization of neocortex. Columnar or clustered
The term column specifically denotes an organization in which groups of neurons with similar properties are extended perpendicularly to the cortical surface. Clustered organization, as used here, is intended to be similar but more general, where the groups of similar neurons need not have any particular geometry. Because of the limits of recording in the alert monkey, these cannot be distinguished in the present work, and the more inclusive term “clustered” will be used. organization of neurons sharing like properties is now known to be widespread, and probably universal in primary sensory areas. Visual cortex in primates consists of a primary area and a large number of secondary areas, which are organized in a manner both hierarchical and parallel (Felleman & Van Essen, 1991; Young, 1993; Young et al., 1995). One major component in the organization of extrastriate visual cortex appears to be the division into dorsal and ventral “streams” of processing (Ungerleider & Mishkin, 1982), each of which is organized hierarchically. Within each, columnar organization exists at early stages, but becomes less clear at higher levels. Columnar organization has been described at the highest level of the ventral stream, inferotemporal cortex (IT, Saleem et al., 1993; Fujita & Fujita, 1996; Tanaka, 1996), but has not been well characterized at the higher levels of the dorsal stream. Hints of such organization are found in the literature (Saito et al., 1986; Lagae et al., 1994), but systematic measurements are needed. In this paper, I report the existence of clustered organization in the medial superior temporal area (MST) of the dorsal stream, which is arguably the highest dominantly visual area on this pathway. I have measured the selectivity of both single- and multiple-unit activity along oblique electrode penetrations through this area to three different kinds of optic flow stimuli, and find that nearby neurons are more similar in their tuning than are more distant ones. This observation documents the existence of some form of clustered organization and supports the importance of this area in the processing of optic flow information.
Target-specific morphology of retinal axon arbors in the adult hamster
- CHANGYING LING, GERALD E. SCHNEIDER, SONAL JHAVERI
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- 01 March 1998, pp. 559-579
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The B fragment of cholera toxin (CT-B) provides a highly sensitive anterograde tracer for labeling retinofugal axons, revealing dense projections to known central retinorecipient nuclei, and sparse but distinct inputs to regions that have not been traditionally recognized as targets of direct retinal projections. In hamsters, we can identify CT-B labeled retinal axons in more than 25 cell groups in the mesencephalon, diencephalon, and basal telencephalon. CT-B labeling additionally delineates the complete arbor morphology, especially in regions that receive a sparse input, offering hitherto unknown views of retinal axon ramifications. We present here the terminal morphology of retinal axons in the lateral geniculate body and superior colliculus, verifying earlier studies, and also document novel findings on the configuration of retinal axon endings in the ventral nucleus of the lateral geniculate body, intergeniculate leaflet, suprachiasmatic nucleus, and in the nuclei of the accessory optic tract. Additionally, the trajectory and terminal morphology of retinal afferents to the hypothalamus, preoptic area, and basal telencephalon are detailed. The results are discussed in the context of possible functional roles for some of these projections.
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Photopigment basis for dichromatic color vision in cows, goats, and sheep
- GERALD H. JACOBS, JESS F. DEEGAN, JAY NEITZ
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- 01 March 1998, pp. 581-584
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Electroretinogram (ERG) flicker photometry was used to measure the spectral properties of cones in three common ungulates—cattle (Bos taurus), goats (Capra hircus), and sheep (Ovis aries). Two cone mechanisms were identified in each species. The location of peak sensitivity of an S-cone mechanism varied from about 444 to 455 nm for the three species; analogous values for an M/L-cone were tightly clumped at about 552–555 nm. Each of these three species has the requisite photopigment basis for dichromatic color vision and they are, thus, similar to other ungulates examined earlier.