Convergence and divergence of cones onto bipolar cells in the central area of cat retina

1990 ◽  
Vol 330 (1258) ◽  
pp. 323-328 ◽  
Keyword(s):  
Bipolar Cell ◽  
Central Area ◽  
Plexiform Layer ◽  
Preceding Paper ◽  
Bipolar Cells ◽  
Visual Signal ◽  
Wide Field ◽  
Inner Plexiform Layer ◽  
Type B ◽  
Cat Retina

In the central area of cat retina the cone bipolar cells that innervate sublamina b of the inner plexiform layer comprise five types, four with narrow dendritic fields and one with a wide dendritic field. This was shown in the preceding paper (Cohen & Sterling 1990 a ) by reconstruction from electron micrographs of serial sections. Here we show by further analysis of the same material that the coverage factor (dendritic spread x cell density) is about one for each of the narrow-field types (b 1 , b 2 , and b 4 ). The same is probably true for the other narrow-field type (b 3 ), but this could not be proved because its dendrites were too fine to trace. The dendrites of types b 1 , b 2 , and b 4 collect from all the cone pedicles within their reach and do not bypass local pedicles in favour of more distant ones. The dendrites of type b 5 , the wide-field cell, bypass many pedicles. On average 5.1±1.0 pedicles converge on a b 1 bipolar cell; 6.0±1.2 converge on a b 2 cell and 5.7±1.5 converge on a b 4 cell. Divergence within a type is minimal: one pedicle contacts only 1.2 b 1 cells, 1.0 b 2 cells, and 1.0 b 4 cells. Divergence across types is broad : each pedicle apparently contacts all four types of the narrow-field bipolar cells that innervate sublamina b . Each pedicle probably also contacts an additional 4—5 types of narrow-field bipolar cell that innervate sublamina a . There are several possible advantages to encoding the cone signal into multiple, parallel, narrow-field pathways. These include: tuning of pathways to transmit different temporal frequencies, use of ion channels with widely separated equilibrium potentials (to increase gain), and formation of different regulatory circuits in the inner plexiform layer. The latter possibility would permit different operations (e.g linear or nonlinear) to be performed on the visual signal on its way towards different types of ganglion cell.

Rod bipolar cells in the cone-dominated retina of the tree shrew Tupaia belangeri

1991 ◽  
Vol 6 (6) ◽  
pp. 629-639 ◽  
Author(s):  
Brigitte Müller ◽  
Leo Peichl
Keyword(s):  
Bipolar Cell ◽  
Tree Shrew ◽  
Light And Electron Microscopy ◽  
Plexiform Layer ◽  
Bipolar Cells ◽  
Peripheral Retina ◽  
Inner Plexiform Layer ◽  
Cat Retina ◽  
Topographical Distribution ◽  
Rod Bipolar Cells

AbstractThe tree shrew has a cone-dominated retina with a rod proportion of 5%, in contrast to the common mammalian pattern of rod-dominated retinae. As a first step to elucidate the rod pathway in the tree shrew retina, we have demonstrated the presence of rod bipolar cells and studied their morphology and distribution by light and electron microscopy.Rod bipolar cells were labeled with an antiserum against the protein kinase C (PKC), a phosphorylating enzyme. Intense PKC immunoreactivity was found in perikarya, axons, and dendrites of rod bipolar cells. The cell bodies are located in the sclerad part of the inner nuclear layer, the dendrites ascend to the outer plexiform layer where they are postsynaptic to rod spherules, and an axon descends towards the inner plexiform layer (IPL). The axons branch, and terminate in the vitread third of the IPL where mammalian rod bipolar cells are known to terminate. Two amacrine cell processes are always seen as the postsynaptic elements (dyads). Dendritic and axonal arbors of rod bipolar cells are rather large, up to 100 μm in diameter. The topographical distribution of the rod bipolar cells was analyzed quantitatively in tangential sections.Their density ranges from 300 cells/mm2 in peripheral retina to 900 cells/mm2 more centrally. The distribution is rather flat with no local extremes. Consistent with the low rod proportion in tree shrew, the rod bipolar cell density is low compared to the rod-dominated cat retina for example (36,000-47,000 rod bipolar cells/mm2). Rod-to-rod bipolar cell ratios in the tree shrew retina range from smaller than 1 to about 7, and thus are also lower than in cat.

Morphology and topography of on- and off-alpha cells in the cat retina

1981 ◽  
Vol 212 (1187) ◽  
pp. 157-175 ◽  
Keyword(s):  
Central Area ◽  
Plexiform Layer ◽  
Preceding Paper ◽  
Alpha Cell ◽  
Inner Plexiform Layer ◽  
Alpha Cells ◽  
Cat Retina ◽  
Topographical Distribution ◽  
Retinal Point ◽  
Dendritic Branches

Neurofibrillar staining methods were found to stain all alpha cells of the cat retina completely, that is the perikaryon, the axon and the dendritic branches. The dendrites of the alpha cells in vertical sections were found to be unistratified and to occupy two narrow strata in the outer half of the inner plexiform layer. This difference in branching level could also be observed in whole-mount preparations and it has been demon­strated in the preceding paper (Peichl & Wässle 1981) that it corre­sponds to the physiological on‒off dichotomy. Thus the topographical distribution of on- and off-alpha cells could be studied. They were found to occur in about equal numbers. Both on- and off-alpha cell perikarya form a regular lattice and both lattices are superimposed independently. The dendritic branches of neighbouring alpha cells overlap and each retinal point is covered by the dendritic field of at least one on- and one off-alpha cell. The dendritic trees of on-alpha cells seem to have more small branches and are on the average smaller than those of off-alpha cells. The density of alpha cells was found to peak in the central area whence it continuously decreased towards the retinal periphery.

The morphology and topographic distribution of AII amacrine cells in the cat retina

1985 ◽  
Vol 224 (1237) ◽  
pp. 475-488 ◽  
Keyword(s):  
Ganglion Cells ◽  
Lucifer Yellow ◽  
Central Area ◽  
Plexiform Layer ◽  
Amacrine Cells ◽  
Dendritic Morphology ◽  
Inner Plexiform Layer ◽  
Cat Retina ◽  
Superior Margin ◽  
Aii Amacrine Cells

When cat retina is incubated in vitro with the fluorescent dye, 4',6- diamidino-2-phenyl-indole (DAPI), a uniform population of neurons is brightly labelled at the inner border of the inner nuclear layer. The dendritic morphology of the DAPI-labelled cells was defined by iontophoretic injection of Lucifer yellow under direct microscopic control: all the filled cells had the narrow-field bistratified morphology that is distinctive of the A ll amacrine cells previously described from Golgistained retinae. Although the A ll amacrines are principal interneurons in the rod-signal pathway, their density distribution does not follow the topography of the rod receptors, but peaks in the central area like the cone receptors and the ganglion cells. There are some 512000 A ll amacrines in the cat retina and their density ranges from 500 cells per square millimetre at the superior margin to 5300 cells per square millimetre in the centre (retinal area is 450 mm2). The isodensity contours are kite-shaped, particularly at intermediate densities, with a horizontal elongation towards nasal retina. The cell body size and the dendritic dimensions of A ll amacrines increase with decreasing cell density. The lobular dendrites in sublamina a of the inner plexiform layer span a restricted field of 16—45 pm diameter, while the arboreal dendrites in sublamina b form a varicose tree of 18—95 pm diameter. The dendritic field coverage of the lobular appendages is close to 1.0 (+ 0.2) at all eccentricities whereas the coverage of the arboreal dendrites doubles within the first 1.5 mm and then remains constant at 3.8 ( + 0.7) throughout the periphery.

Glycine receptor immunoreactivity is localized at amacrine synapses in cat retina

1991 ◽  
Vol 7 (6) ◽  
pp. 611-618 ◽  
Author(s):  
Roberta G. Pourcho ◽  
Michael T. Owczarzak
Keyword(s):  
Ganglion Cells ◽  
Glycine Receptor ◽  
Plexiform Layer ◽  
Amacrine Cells ◽  
Bipolar Cells ◽  
Electron Microscopic Level ◽  
Inner Plexiform Layer ◽  
Glycine Receptors ◽  
Electron Microscopic ◽  
Cat Retina

AbstractImmunocytochemical techniques were used to localize strychnine-sensitive glycine receptors in cat retina. Light microscopy showed staining in processes ramifying throughout the inner plexiform layer and in cell bodies of both amacrine and ganglion cells. At the electron-microscopic level, receptor immunoreactivity was seen to be clustered at sites postsynaptic to amacrine cells. In contrast, bipolar cells were neither presynaptic nor postsynaptic elements at sites of glycine receptor staining. Double-label studies verified the presence of glycine immunoreactivity in amacrine terminals presynaptic to glycine receptors. These findings support a role for glycine as an inhibitory neurotransmitter in amacrine cells.

In vivo development of retinal ON-bipolar cell axonal terminals visualized in nyx::MYFP transgenic zebrafish

2006 ◽  
Vol 23 (5) ◽  
pp. 833-843 ◽  
Author(s):  
ERIC H. SCHROETER ◽  
RACHEL O.L. WONG ◽  
RONALD G. GREGG
Keyword(s):  
Bipolar Cell ◽  
Plexiform Layer ◽  
Transgenic Fish ◽  
Bipolar Cells ◽  
Regulatory Sequences ◽  
Inner Plexiform Layer ◽  
Fixed Tissue ◽  
Different Ages ◽  
Retinal Bipolar Cells

Axonal differentiation of retinal bipolar cells has largely been studied by comparing the morphology of these interneurons in fixed tissue at different ages. To better understand how bipolar axonal terminals develop in vivo, we imaged fluorescently labeled cells in the zebrafish retina using time-lapse confocal and two photon microscopy. Using the upstream regulatory sequences from the nyx gene that encodes nyctalopin, we constructed a transgenic fish in which a subset of retinal bipolar cells express membrane targeted yellow fluorescent protein (MYFP). Axonal terminals of these YFP-labeled bipolar cells laminated primarily in the inner half of the inner plexiform layer, suggesting that they are likely to be ON-bipolar cells. Transient expression of MYFP in isolated bipolar cells indicates that two or more subsets of bipolar cells, with one or two terminal boutons, are labeled. Live imaging of YFP-expressing bipolar cells in the nyx::MYFP transgenic fish at different ages showed that initially, filopodial-like structures extend and retract from their primary axonal process throughout the inner plexiform layer (IPL). Over time, filopodial exploration becomes concentrated at discrete foci prior to the establishment of large terminal boutons, characteristic of the mature form. This sequence of axonal differentiation suggests that synaptic targeting by bipolar cell axons may involve an early process of trial and error, rather than a process of directed outgrowth and contact. Our observations represent the first in vivo visualization of axonal development of bipolar cells in a vertebrate retina.

scholarly journals Heterocellular coupling between amacrine cell and ganglion cells

2018 ◽  
Author(s):  
Robert E. Marc ◽  
Crystal Sigulinsky ◽  
Rebecca L. Pfeiffer ◽  
Daniel Emrich ◽  
James R. Anderson ◽  
...  
Keyword(s):  
Gap Junctions ◽  
Ganglion Cell ◽  
Bipolar Cell ◽  
Amacrine Cell ◽  
Ganglion Cells ◽  
Plexiform Layer ◽  
Amacrine Cells ◽  
Bipolar Cells ◽  
Inner Plexiform Layer ◽  
Tem Analysis

AbstractAll superclasses of retinal neurons display some form of electrical coupling including the key neurons of the inner plexiform layer: bipolar cells (BCs), amacrine or axonal cells (ACs) and ganglion cells (GCs). However, coupling varies extensively by class. For example, mammalian rod bipolar cells form no gap junctions at all, while all cone bipolar cells form class-specific coupling arrays, many of them homocellular in-superclass arrays. Ganglion cells are unique in that classes with coupling predominantly form heterocellular cross-class arrays of ganglion cell::amacrine cell (GC::AC) coupling in the mammalian retina. Ganglion cells are the least frequent superclass in the inner plexiform layer and GC::AC gap junctions are sparsely arrayed amidst massive cohorts of AC::AC, bipolar cell BC::BC, and AC::BC gap junctions. Many of these gap junctions and most ganglion cell gap junctions are suboptical, complicating analysis of specific ganglion cells. High resolution 2 nm TEM analysis of rabbit retinal connectome RC1 allows quantitative GC::AC coupling maps of identified ganglion cells. Ganglion cells classes apparently avoid direct cross-class homocellular coupling altogether even though they have opportunities via direct membrane touches, while transient OFF alpha ganglion cells and transient ON directionally selective (DS) ganglion cells are strongly coupled to distinct amacrine / axonal cell cohorts.A key feature of coupled ganglion cells is intercellular metabolite flux. Most GC::AC coupling involves GABAergic cells (γ+ amacrine cells), which results in significant GABA flux into ganglion cells. Surveying GABA coupling signatures in the ganglion cell layer across species suggests that the majority of vertebrate retinas engage in GC::AC coupling.Multi-hop synaptic queries of the entire RC1 connectome clearly profiles the coupled amacrine and axonal cells. Photic drive polarities and source bipolar cell class selec-tivities are tightly matched across coupled cells. OFF alpha ganglion cells are coupled to OFF γ+ amacrine cells and transient ON DS ganglion cells are coupled to ON γ+ amacrine cells including a large interstitial axonal cell (IAC). Synaptic tabulations show close matches between the classes of bipolar cells sampled by the coupled amacrine and ganglion cells. Further, both ON and OFF coupling ganglion networks show a common theme: synaptic asymmetry whereby the coupled γ+ neurons are also presynaptic to ganglion cell dendrites from different classes of ganglion cells outside the coupled set. In effect, these heterocellular coupling patterns enable an excited ganglion cell to directly inhibit nearby ganglion cells of different classes. Similarly, coupled γ+ amacrine cells engaged in feedback networks can leverage the additional gain of bipolar cell synapses in shaping the signaling of a spectrum of downstream targets based on their own selective coupling with ganglion cells.

scholarly journals Pharmacology of the skate electroretinogram indicates independent ON and OFF bipolar cell pathways.

1996 ◽  
Vol 107 (4) ◽  
pp. 535-544 ◽  
Author(s):  
R L Chappell ◽  
F J Rosenstein
Keyword(s):  
Bipolar Cell ◽  
Visual Information ◽  
Plexiform Layer ◽  
Bipolar Cells ◽  
Inner Plexiform Layer ◽  
Critical Feature ◽  
Single Class ◽  
Afferent Pathways ◽  
Afferent Information ◽  
On And Off Pathways

Organization of afferent information into parallel ON and OFF pathways is a critical feature of the vertebrate visual system. All afferent visual information in the vertebrate retina reaches the inner plexiform layer (IPL) via bipolar cells. It is at the bipolar cell level that separation of ON and OFF information first appears for afferent information from cones. This may also hold true for the rod pathway of cold-blooded vertebrates, but not for mammals. The all-rod retina of the skate presents an opportunity to examine such pathways in a retina having but a single class of photoreceptor. Immunocytochemical evidence suggests that both ON and OFF bipolar cells are present in the skate retina. We examined the pharmacology of the skate electroretinogram (ERG) to test the hypothesis that independent ON and OFF bipolar cell pathways are functional as rod afferent pathways from outer to inner plexiform layer in the skate. 100 microM 2-amino-4-phosphonobutyric acid (APB) reversibly blocked the skate ERG b-wave. A small d-wave-like OFF component of the ERG revealed by DC recording of response to a prolonged (10 s) flash of light was reduced or blocked by 5 mM kynurenic acid (KYN). We found that addition of 200 microM picrotoxin to the Ringer's solution revealed prominent ON and OFF components of the skate ERG while reducing the c-wave. These ON and OFF components were reversibly blocked by 100 microM APB and 5 mM KYN, respectively. Reversible block of the OFF component by KYN was also accomplished in the presence of 500 microM N-methyl-DL-aspartate. From these findings, we conclude that ON and OFF bipolar cells are likely to be functional as parallel afferent interplexiform pathways in the all-rod retina of the skate.

Differential distribution of synaptotagmin immunoreactivity among synapses in the goldfish, salamander, and mouse retina

2003 ◽  
Vol 20 (1) ◽  
pp. 37-49 ◽  
Author(s):  
RUTH HEIDELBERGER ◽  
MENG M. WANG ◽  
DAVID M. SHERRY
Keyword(s):  
Posttranslational Modifications ◽  
Bipolar Cell ◽  
Plexiform Layer ◽  
Bipolar Cells ◽  
Mouse Retina ◽  
Inner Plexiform Layer ◽  
Calcium Sensor ◽  
Differential Distribution ◽  
Western Blots ◽  
Goldfish Retina

Synaptotagmin I is the leading candidate for the calcium sensor that triggers exocytosis at conventional synapses. However, physiological characterization of the calcium sensor for phasic release at the ribbon-style synapses of the goldfish Mb1 bipolar cell demonstrates a lower than predicted affinity for calcium, suggesting that a modified or different sensor triggers exocytosis at this synapse. We examined synaptotagmin immunolabeling in goldfish retina using two different antibodies directed against synaptotagmin epitopes that specifically labeled the expected 65-kDa protein on western blots of goldfish and mouse retinal membranes. The first antiserum strongly labeled conventional synapses in the inner plexiform layer (IPL), but did not label the ribbon-style synapse-containing synaptic terminals of goldfish Mb1 bipolar cells or photoreceptors. The second antibody also specifically labeled the expected 65-kDa protein on western blots but did not label any synapses in the goldfish retina. A third synaptotagmin antibody that performed poorly on western blots selectively labeled goldfish photoreceptor terminals. These results suggest that synaptotagmin may exist in at least three distinct “forms” in goldfish retinal synapses. These forms, which are differentially localized to conventional synapses, bipolar cell, and photoreceptor terminals, may represent differences in isoform, posttranslational modifications, epitope availability, and protein-binding partners. Labeling with these antibodies in the salamander and mouse retina revealed species-specific differences, indicating that synaptotagmin epitopes can vary across species as well as among synapses.

Light responses from one type of ON-OFF amacrine cells in the rabbit retina

1995 ◽  
Vol 74 (6) ◽  
pp. 2460-2468 ◽  
Author(s):  
R. F. Dacheux ◽  
E. Raviola
Keyword(s):  
Light Adaptation ◽  
Receptive Fields ◽  
Central Area ◽  
Plexiform Layer ◽  
Light Response ◽  
Amacrine Cells ◽  
Wide Field ◽  
Inner Plexiform Layer ◽  
Rabbit Retina ◽  
Light Responses

1. The light responses from one type of ON-OFF amacrine cell were recorded intracellularly in the superfused rabbit retina under various conditions of light adaptation. These recordings were obtained from cells located in a central area. 5-7 mm inferior and directly below the optic nerve head. 2. ON-OFF amacrine cells responded to the initiation and termination of light stimuli with transient depolarizations. Their receptive fields were approximately 0.8-1 mm diam and did not exhibit antagonistic center-and-surround organization. 3. The cells received rod input because they responded to very dim scotopic stimuli. With prolonged dark adaptation, the cells became more sensitive to the initiation than termination of the stimulus, because the ON component of the light response had a lower threshold than the OFF component. 4. The cells continued to respond to test flashes when the retina was adapted to a background illumination of rod-saturating intensity. Thus ON-OFF amacrine cells also receive cone input. Under these photopic conditions, a secondary afterpotential was observed following the OFF component. Its characteristics were different from those of the rod aftereffect reported in other retinal cells of the rabbit because its latency and amplitude changed with increasing stimulus intensity. 5. Intracellular injections of horseradish peroxidase showed that the recordings were obtained from a class of ON-OFF amacrine cells whose wide-field, unistratified dendrites were rigorously confined to the middle of the inner plexiform layer or stratum 3. 6. The conspicuous rod and cone inputs into a class of amacrine cells that are connected neither to rod bipolars nor to All amacrine cells strongly support the idea that in the rabbit the rod pathway uses cone bipolars as interneurons to distribute scotopic signals to ganglion and cone-driven amacrine cells.

Demonstration of cell types among cone bipolar neurons of cat retina

1990 ◽  
Vol 330 (1258) ◽  
pp. 305-321 ◽  
Keyword(s):  
Large Population ◽  
Plexiform Layer ◽  
Cell Types ◽  
Bipolar Cells ◽  
Inner Plexiform Layer ◽  
Regular Array ◽  
Cat Retina ◽  
Area Centralis ◽  
Ultrathin Sections ◽  
Total Reconstruction

We identified all the cone bipolar cells (80) in a small patch of one retina and then studied in detail the complete subset (42) that sends axons to sublamina b of the inner plexiform layer. The point was to learn whether the ‘types' suggested previously, based on a few examples from a large population, could be substantiated or whether there would be intermediate forms. Tissue from the area centralis (1° eccentricity), was prepared as a series of 279 ultrathin sections and photographed in the electron microscope. Thirteen cells were reconstructed completely and parcelled into five categories (b 4 —b 5 ) based on external morphology. For nine of these cells (two from categories b 1 -b 4 and one from b 5 ) most of the synaptic inputs and outputs were identified. When these nine cells were parcelled according to their synaptic patterns, they sorted into the same five categories. The remaining 29 cells in the population, though not reconstructed, were studied in detail by tracing their processes through the series. Ten of these cells, those near the margin of the series, were incomplete. The other 19 cells had essentially the same distribution of morphologies and synaptic patterns as the subset studied by total reconstruction: when plotted in multiparametric space, they formed distinct clusters corresponding to the five morphological categories. There was no hint of intermediate forms. That all the neurons in the population sort into some cluster (no intermediate forms), and that each neuron sorts into the same cluster by different criteria, argues that the clusters represent natural types. Each type forms a regular array in the region studied with an axonal ‘coverage factor' that is close to one.

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