Displaced horizontal cells in the chick retina

The retina of the chick contains retinal cells of a morphology very similar to that of the horizontal cells, but the perikarya, axons, and axon terminals lie in the inner plexiform layer. The discovery of this neuronal ectopia appears to support the idea that some horizontal and amacrine cells derive from a common, freely migrating cell.     

Interaction between horizontal cells of the turtle retina

Interaction between horizontal cells of the turtle retina was studied by two microelectrodes (polarizing and recording), inserted into different cells at different distances apart. The presence of a direct electrical connection was demonstrated between the L cells of the same type (I, with large, and II, with small receptive fields). Its magnitude depends on the conditions of illumination and the level of the membrane potential, possibly because of the properties of the subsynaptic and nonsynaptic membranes of the horizontal cells. No direct electrical connection exists between L cells of different types. However, hyperpolarization of the type I cells through the microelectrode or by stimulation with a circle of light evoked depolarization in the type II cells. This indirect connection between the horizontal cells, also dependent on the conditions of illumination, can probably be explained by feedback to these cells from the photoreceptors. Polarization of L cells of both types had no effect on horizontal cells of color type.     

Ion exchange in the horizontal cells of the retina

Experimental data indicate that the membrane potential of L-type horizontal cells of the retina to bright light (i.e., when synaptic inputs are completely closed) is close to the potassium equilibrium potential. From this observation the intracellular concentration of K⁺ and Na⁺ was estimated. The latter was found to be relatively high (tens of millimoles/liter), i.e., comparable with the intracellular K⁺ concentration. This result, coupled with data on closeness of the equilibrium potential of the photic response to zero, is evidence that besides sodium conductance, the potassium conductance of the subsynaptic membrane also participates in generation of the photic response by these cells. The steady-state sodium and potassium synaptic currents was shown to be relatively small and to vary only a little over the whole working range of potentials (from –72 to –16 mV), due to the nonlinear properties of the nonsynaptic cell membrane.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 14, No. 1, pp. 3–10, January–February, 1982.     

Membrane potential clamping in horizontal cells of the fish retina

The membrane potential of horizontal cells of the retina was clamped by uniform polarization of the layer of these cells by a current passed through extracellular electrodes. The volt-ampere characteristic curve of the synaptic membrane of the horizontal cells in some cases had segments with negative slope. With a sharp change in the level of voltage clamping the time taken for the resistance of the membrane to change was under 20 msec. Comparison of responses to photic stimulation recorded with and without voltage clamping showed that participation of the nonsynaptic membrane in the generation of responses to photic stimulation can affect their shape substantially.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 9, No. 4, pp. 402–407, July–August, 1977.     

Dynamics of chromaticity horizontal cells in the freshwater turtle retina

A model of the cone-horizontal cell circuit is presented based on morphological evidence recently found in the Reeves' turtle: a luminosity horizontal cell (LHC) that receives inputs from red-, green-, and blue-sensitive cones in the ratio of 15:3:1, a triphasic horizontal cell (THC) that receives inputs from one class of red-sensitive and from blue-sensitive cones in the ratio of 2:1; and a biphasic chromaticity horizontal cell (BHC) that receives inputs from green-sensitive cones as well as from a special class of red-sensitive (i.e. the broad spectrum) and from blue-sensitive cones in the ratio of 3:2:1. A study of the simulated impulse responses strongly suggests that the basic response patterns of the BHC and THC can be readily explained by a simple wiring diagram consisting of direct hyper-polarizing inputs from the appropriate cones and a depolarizing input from the LHC which acts as a voltage inverter. A negative feedback circuit from the LHC to the cone pedicles is included and its negative feedback gain increases as the mean illuminance level (Io) increases. The negative feedback circuit, which promotes adaptation in the cones to changing Io's, is not necessary for opponent polarization in the BHC or THC, but does explain variabilities of impulse responses.     

Receptive field properties of rod-driven horizontal cells in the skate retina

The large receptive fields of retinal horizontal cells result primarily from extensive intercellular coupling via gap (electrical) junctions; thus, the extent of the receptive field provides an index of the degree to which the cells are electrically coupled. For rod-driven horizontal cells in the dark-adapted skate retina, a space constant of 1.18 +/- 0.15 mm (SD) was obtained from measurements with a moving slit stimulus, and a comparable value (1.43 +/- 0.55 mm) was obtained with variation in spot diameter. These values, and the extensive spread of a fluorescent dye (Lucifer Yellow) from the site of injection to neighboring cells, indicate that the horizontal cells of the all-rod retina of skate are well coupled electrically. Neither the receptive field properties nor the gap-junctional features of skate horizontal cells were influenced by the adaptive state of the retina: (a) the receptive field organization was unaffected by light adaptation, (b) similar dye coupling was seen in both dark- and light-adapted retinae, and (c) no significant differences were found in the gap-junctional particle densities measured in dark- and light-adapted retinas, i.e., 3,184 +/- 286/microns 2 (n = 8) and 3,073 +/- 494/microns 2 (n = 11), respectively. Moreover, the receptive fields of skate horizontal cells were not altered by either dopamine, glycine, GABA, or the GABAA receptor antagonists bicuculline and picrotoxin. We conclude that the rod-driven horizontal cells of the skate retina are tightly coupled to one another, and that the coupling is not affected by photic and pharmacological conditions that are known to modulate intercellular coupling between cone-driven horizontal cells in other species.     

Topography of horizontal cells in the retina of the domestic cat.

Neurofibrillar methods stain a class of horizontal cells in the cat retina which are shown to be identical with the A-type horizontal cell of Golgi-staining. Thus all of the A-type cells of a single retina can be observed. On this basis the changes in density and dendritic field size of A-type horizontal cells with respect to retinal eccentricity were measured. The decrease in density from centre to periphery is balanced by a corresponding increase in size of the dendritic field. Consequently each retinal point--independent of retinal position--is covered by the dendritic fields of three of four A-type horizontal cells. The nuclei and nucleoli of B-type horizontal cells could also be recognized in neurofibrillar-stained material and thus their distribution was determined. The density ratio B-type: A-type is 2.8 +/- 0.4 and does not vary much from the centre to the periphery of the retina. Each retinal point is also covered by four B-type horizontal cells. Thus a single cone can contact a maximum of eight horizontal cells. The rate of density decrease from centre to periphery is closely similar in cones and horizontal cells but greater in ganglion cells.     

Model feedback mechanism between horizontal cells and photoreceptors of the vertebrate retina

A model with nonlinearity of the photoreceptor presynaptic membrane as its important distinguishing feature was created on the basis of the hypothesis that feedback between the horizontal cells and photoreceptors is effected by a current generated by the subsynaptic membrane of the horizontal cells and leaking partly into the photoreceptors. Measurements with the model also reproduced experimental observations such as depolarization of the cone during hyperpolarization of the horizontal cell in response to the showing of a ring of light or passage of an electric current, and also certain special features of the current-voltage curves of the cones.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 86–94, January–February, 1977.     

Receptor contacts of horizontal cells in the retina of the domestic cat.

The terminal aggregations of A- and B-type horizontal cells, stained by the Golgi-Colonnier method, have been analysed. The pattern of the aggregations is regular and is shown to be in register with the cone mosaic. Both tyes of horizontal cell are in contact with at least 80% of the cones above their dendritic fields. Therefore, the different horizontal cell classes cannot be selective for a special kind of cone but must have at least 60% of the cone input in common. Each A-type horizontal cell makes contacts with between 120 and 170 cones, and each B-type horizontal cell with 60-90 cones. An individual A-type horizontal cell occupies an average of 20% of the lateral elements of the triads in a cone pedicle, but an individual B-type cell fills only some 13%. Each and every cone is connected with several of both types of horizontal cell. An estimation of the number of rods converging onto a single axon terminal system showed that it could be as many as 3000.     

Color opponency in cone-driven horizontal cells in carp retina. Aspecific pathways between cones and horizontal cells

The spectral and dynamic properties of cone-driven horizontal cells in carp retina were evaluated with silent substitution stimuli and/or saturating background illumination. The aim of this study was to describe the wiring underlying the spectral sensitivity of these cells. We will present electrophysiological data that indicate that all cone-driven horizontal cell types receive input from all spectral cone types, and we will present evidence that all cone-driven horizontal cell types feedback to all spectral cone types. These two findings are the basis for a model for the spectral and dynamic behavior of all cone-driven horizontal cells in carp retina. The model can account for the spectral as well as the dynamic behavior of the horizontal cells. It will be shown that the strength of the feedforward and feedback pathways between a horizontal cell and a particular spectral cone type are roughly proportional. This model is in sharp contrast to the Stell model, where the spectral behavior of the three horizontal cell types is explained by a cascade of feedforward and feedback pathways between cones and horizontal cells. The Stell model accounts for the spectral but not for the dynamic behavior of the horizontal cells.     

Sustained and transient calcium currents in horizontal cells of the white bass retina

Calcium currents were recorded from cultured horizontal cells (HCs) isolated from adult white bass retinas, using the whole-cell patch-clamp technique. Ca2+ currents were enhanced using 10 mM extracellular Ca2+, while Na+ and K+ currents were pharmacologically suppressed. Two components of the Ca2+ current, one transient, the other sustained, were found. The large transient component of the Ca2+ current, which has not been seen before in HCs, is similar, but not identical, to the T-type Ca2+ current described previously in a variety of preparations. The sustained component of the Ca2+ current is similar, but not identical, to the L-type current described in other preparations. FTX, a factor isolated from the venom of the funnel-web spider, Agelenopsis aperta, preferentially and irreversibly blocks the sustained component of the Ca2+ current at very dilute concentrations. The sustained component of the Ca2+ current inactivates slowly, over the course of 15-60 s, in some HCs. This inactivation of the sustained Ca2+ current, when present, is primarily voltage dependent rather than Ca2+ dependent.     

Electrical properties of subsynaptic and nonsynaptic membranes of horizontal cells of the turtle retina

Horizontal cells of the L-type in the turtle retina were polarized by passing a steady current through extracellular electrodes. In this way controlled changes in membrane potential can be effectively produced in the region of the cell body. The hyperpolarization response of the horizontal cell to light is reversed on depolarization of the cell membrane to about the zero level. Consequently, the response of the horizontal cell to light is the result of a decrease in the EPSP, the magnitude of which remains constant in darkness. The resistance of the cell membrane depends on the membrane potential. Hyperpolarization of horizontal cells produced by bright light or by passage of a steady current was accompanied by a decrease in their membrane resistance. This nonlinearity evidently depends on the properties of the nonsynaptic membrane of the horizontal cells, whose resistance falls considerably on hyperpolarization. The results are qualitatively similar to those demonstrated previously [10] in an investigation of the horizontal cells of the fish retina.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 5, No. 4, pp. 423–431, July–August, 1973.     

Immunocytochemical detection of 28000-MW calcium-binding protein in horizontal cells of the rat retina

Summary Horizontal cells of rat retina were labeled intensely by a specific antibody to cerebellar calcium-binding protein. The amacrine cells stained very weakly. The presence of calcium-binding protein in horizontal cells could be of interest for the understanding of the feedback action of these cells on photoreceptors.Abbreviations used CaBP calcium-binding protein - DAB 3,3-diaminobenzidine - PAP unlabelled antibody peroxidase-antiperoxidase immunocytochemical complex On leave from the Department of Physiology, University of British Columbia, Vancouver, Canada