Horizontal cells of mammalian retinae

3D engineering for optic neuropathy treatment

Ocular disorders, such as age-related macular degeneration (AMD), diabetic retinopathy (DR), retinitis pigmentosa (RP), and glaucoma, can cause irreversible visual loss, and affect the quality of life of millions of patients. However, only very few 3D systems can mimic human ocular pathophysiology, especially the retinal degenerative diseases, which involve the loss of retinal ganglion cells (RGCs), photoreceptors, or retinal pigment epithelial cells (RPEs). In this review, we discuss current progress in the 3D modeling of ocular tissues, and review the use of the aforementioned technologies for optic neuropathy treatment according to the categories of associated disease models and their applications in drug screening, mechanism studies, and cell and gene therapies.

Specificity of the horizontal cell-photoreceptor connections in the zebrafish (Danio rerio) retina

Horizontal cells (HCs) are involved in establishing the center-surround receptive field organization of photoreceptor and bipolar cells. In many species, HCs respond differentially to colors and may play a role in color vision. An earlier study from our laboratory suggested that four types of HCs exist in the zebrafish retina: three cone HCs (H1, H2 and H3) and one rod HC. In this study, we describe their photoreceptor connections. Cones are arranged in a mosaic in which rows of alternating blue (B)- and ultraviolet (UV)-sensitive single cones alternate with rows of red (R)- and green (G)-sensitive double cones; the G cones are adjacent to UV cones and B cones adjacent to R cones. Two small-field (H1 and H2) and two large-field (H3 and rod HC) cells were observed. The cone HC dendritic terminals connected to cones with single boutons, doublets, or rosettes, whereas the rod HCs connected to rods with single boutons. The single boutons/doublets/rosettes of cone HCs were arranged in double rows separated by single rows for H1 cells, in pairs and singles for H2 cells, and in a rectilinear pattern for H3 cells. These connectivity patterns suggest that H1 cells contact R, G, and B cones, H2 cells G, B, and UV cones, and H3 cells B and UV cones. These predictions were confirmed by applying the DiI method to SWS1-GFP retinas whose UV cones express green fluorescent protein. Each rod HC was adjacent to the soma or axon of a DiI-labeled cone HC and connected to 50-200 rods.

Horizontal cell differentiation in the retina of the Brazilian opossum, Monodelphis domestica

Differentiation of many diverse neuronal phenotypes is an essential part of nervous system development. We have studied the differentiation of horizontal cells, one of the basic neuronal types in the vertebrate retina, in a small, easily maintained marsupial by immunocytochemistry using antineurofilament and antivimentin antibodies. At birth the retina consists of proliferating neural epithelial cells, with a few early ganglion cells. Horizontal cells were first detected in 12-day-old pups; somas were within the epithelial neuroblastic layer and processes extended radially. By 19 days there were tangentially oriented dendrites and a few longer processes, the beginning of the outer plexiform (first synaptic) layer. By the time of eye opening (about 34 days) the basic histological organization of the mature retina was established. In the mature retina and during development, horizontal cell neurites in the outer plexiform layer, as well as ganglion cell axons, reacted strongly with several antineurofilament antibodies and with antivimentin; horizontal cell somas were detected only with one antineurofilament antibody. Only one population was detected, which we identify as the short-axon subtype, by comparison with horizontal cells in other marsupials and in eutherian mammals. This is the first description of the putative absence in a marsupial of one of the two horizontal cell subtypes found in most amniotes, including mammals so far studied, except murid rodents, which have only the short-axon subtype. Absence of one subtype in Monodelphis supports the hypothesis that the short-axon cell is the basic conserved phenotype of this class and suggests that experimental analysis of differentiation of horizontal cells in Monodelphis and murid rodents, compared to marsupials and eutherian mammals which have the basic two subtypes, can help elucidate mechanisms for controlling differentiation of specific cellular phenotypes and the variations in neurons within and among species.

Selective synaptic distribution of kainate receptor subunits in the two plexiform layers of the rat retina

The synaptic localization of the kainate receptor subunits GluR6/7 and KA2 and of the ionotropic glutamate receptor subunits delta1/2 was studied in the rat retina using receptor-specific antisera. GluR6/7 and KA2 were present in both synaptic layers of the retina: the inner plexiform layer (IPL) and the outer plexiform layer (OPL). The localization of delta1/2 was restricted to the IPL. Detailed ultrastructural examination showed that in the OPL GluR6/7 was localized in horizontal cell processes postsynaptic to both rod spherules and cone pedicles. It was always only one of the two invaginating horizontal cell processes at the photoreceptor synapses labeled for GluR6/7. KA2 in the OPL was found only postsynaptic to cone pedicles and never postsynaptic to rod spherules. The KA2-labeled processes made flat contacts with the cone pedicles, suggesting they are the dendrites of OFF bipolar cells. In the IPL the different receptor subunits were localized postsynaptically to ribbon synapses of both rod and cone bipolar cells. As a rule, only one of the two postsynaptic elements at the bipolar cell dyad was stained for each of the receptor subunits examined. The selective and heterogeneous distribution of these receptors at the ribbon synapses of the OPL and IPL suggests a high degree of differential processing of the glutamatergic signals.

Horizontal Cells in the Monkey Retina: Cone connections and dendritic network

Horizontal cells of the macaque monkey retina were quantified and the number of cones converging onto an individual horizontal cell as well as the number of horizontal cells contacting a single cone were determined. This was done by combining data from individual horizontal cells stained by the Golgi method with the results of immunocytochemical staining described in the preceding paper (Röhrenbeck et al., 1989). The observation (Boycott et al., 1987) that all horizontal cells contact all cones in their dendritic field irrespective of cone type was confirmed. The particular cones contacted by the terminal aggregates of each horizontal cell were found. The dendritic fields of H1 and H2 cells increase with increasing eccentricity; close to the fovea H1 cells are smaller than H2 cells, at 6 mm eccentricity they are about the same size and in peripheral retina H1 cells are much larger than H2 cells. The density gradients of the two cell types balance their denritic field changes so that throughout the retina each and every cone synapses with 3 - 5 horizontal cells of each type. Horizontal cells of both cat (Wässle et al., 1978) and monkey retina follow the general rule that all cones in the dendritic fields are contacted, their perikarya form a regular mosaic and the boundaries of their dendritic fields are marked by the perikarya of their homologous neighbours.