Axon-bearing and axon-less horizontal cell subtypes are generated consecutively during chick retinal development from progenitors that are sensitive to follistatin.

BACKGROUND: Horizontal cells are retinal interneurons that modulate the output from photoreceptors. A rich literature on the morphological classification and functional properties of HCs in different animals exists, however, the understanding of the events underlying their development is still limited. In most vertebrates including chicken, two main horizontal cell (HC) subtypes are identified based on the presence or absence of an axon. RESULTS: In this work we have molecularly characterized three HC subtypes based on Lim1, Isl1, GABA and TrkA, a classification that is consistent with three chick HC subtypes previously defined by morphology. The axon-bearing and axon-less HC subpopulations molecularly defined by Lim1 and Isl1, are born consecutively on embryonic day (E) 3-4 and E4-5, respectively, and exhibit temporally distinguishable periods of migration. Their relative numbers are not adjusted by apoptosis. A sharp decrease of high endogenous levels of the activin-inhibitor follistatin at E3 coincides with the appearance of the Lim1 positive cells. Extending the follistatin exposure of the HC retinal progenitor cells by injection of follistatin at E3 increased the number of both Lim1- and Isl1 positive HCs when analysed at E9. CONCLUSION: The results imply that the axon-bearing and axon-less HC subgroups are defined early and are generated consecutively from a retinal progenitor cell population that is sensitive to the inhibitory action of follistatin. The results are consistent with a model wherein added follistatin causes HC-generating progenitors to proliferate beyond the normal period of HC generation, thus producing extra HCs of both types that migrate to the HC layer.

Temporal and spatial expression of transcription factors FoxN4, Ptf1a, Prox1, Isl1 and Lim1 mRNA in the developing chick retina.

Transcription factors are pivotal in regulating cell fate and development. We analyzed five transcription factors - FoxN4, Ptf1a, Prox1, Isl1 and Lim1 - with putative functions in the formation of early-generated retinal interneurons. A full-length chicken FoxN4 cDNA was characterized and in situ as well as RT-PCR showed that FoxN4 expression commenced already in the stage 12-14 optic vesicles. Ptf1a, Prox1, Isl1 and Lim1 expression appeared later by stage 20-24, concomitant with the first post-mitotic ganglion-, amacrine- and horizontal cells. The FoxN4 and Ptf1a expression was transient with peak levels by stage 32-35. Expression disappeared as the retinal progenitor cells differentiated. Prox1, Isl1 and Lim1 expression remained in several differentiated cells including the horizontal cells. The order of expression supports a scheme where Ptf1a and Prox1 is downstream of FoxN4 and that FoxN4 and Ptf1a have transient roles during fate specification while Prox1, Isl1 and Lim1 have roles that are important for the generation of the neuronal subtypes.

Differential expression of duplicated VAL-opsin genes in the developing zebrafish.

Non-visual opsins mediate various light-dependent physiological events. Our previous search for non-visual opsin genes in zebrafish led to the discovery of VAL-opsin (VAL-opsinA) in deep brain cells and retinal horizontal cells of the adult fish. In this study, we report the identification and characterization of its duplicated gene, VAL-opsinB, in zebrafish. A molecular phylogenetic analysis indicates that VAL-opsinB is orthologous to a previously reported salmon gene and that the duplication of the VAL-opsin gene occurred in the teleost lineage. The recombinant protein of zebrafish VAL-opsinB forms a green-sensitive photopigment when reconstituted with 11-cis-retinal. VAL-opsinB expression was detected in a limited number of cells of the brain and the eye, and the expression pattern is distinct from that of the VAL-opsinA gene. Such a differential expression pattern suggests that VAL-opsinA and VAL-opsinB are involved in different physiological events in zebrafish.

Lim1 is essential for the correct laminar positioning of retinal horizontal cells.

Although much is known about the transcriptional regulation that coordinates retinal cell fate determination, very little is known about the developmental processes that establish the characteristic laminar architecture of the retina, in particular, the specification of neuronal positioning. The LIM class homeodomain transcription factor Lim1 (Lhx1) is expressed in postmitotic, differentiating, and mature retinal horizontal cells. We show that conditional ablation of Lim1 results in the ectopic localization of horizontal cells to inner aspects of the inner nuclear layer, among the retinal amacrine cells. The ectopic cells maintain a molecular phenotype consistent with horizontal cell identity; however, these neurons adopt a unique morphology more reminiscent of amacrine cells, including a dendritic arbor positioned within the inner plexiform layer. All other retinal cell populations appear unaltered. Our data suggest a model whereby Lim1 lies downstream of horizontal cell fate determination factors and functions cell autonomously to instruct differentiating horizontal cells to the appropriate laminar position in the developing retina. This study is the first to describe a cell type-specific genetic program that is essential for targeting a discrete retinal neuron population to the proper lamina.

Nonapical symmetric divisions underlie horizontal cell layer formation in the developing retina in vivo.

Symmetric cell divisions have been proposed to rapidly increase neuronal number late in neurogenesis, but how critical this mode of division is to establishing a specific neuronal layer is unknown. Using in vivo time-lapse imaging methods, we discovered that in the laminated zebrafish retina, the horizontal cell (HC) layer forms quickly during embryonic development upon division of a precursor cell population. The precursor cells morphologically resemble immature, postmitotic HCs and express HC markers such as ptf1a and Prox1 prior to division. These precursors undergo nonapical symmetric division at the laminar location where mature HCs contact photoreceptors. Strikingly, the precursor cell type we observed generates exclusively HCs. We have thus identified a dedicated HC precursor, and our findings suggest a mechanism of neuronal layer formation whereby the location of mitosis could facilitate rapid contact between synaptic partners.

Ptf1a determines horizontal and amacrine cell fates during mouse retinal development.

The vertebrate neural retina comprises six classes of neurons and one class of glial cells, all derived from a population of multipotent progenitors. There is little information on the molecular mechanisms governing the specification of cell type identity from multipotent progenitors in the developing retina. We report that Ptf1a, a basic-helix-loop-helix (bHLH) transcription factor, is transiently expressed by post-mitotic precursors in the developing mouse retina. Recombination-based lineage tracing analysis in vivo revealed that Ptf1a expression marks retinal precursors with competence to exclusively produce horizontal and amacrine neurons. Inactivation of Ptf1a leads to a fate-switch in these precursors that causes them to adopt a ganglion cell fate. This mis-specification of neurons results in a complete loss of horizontal cells, a profound decrease of amacrine cells and an increase in ganglion cells. Furthermore, we identify Ptf1a as a primary downstream target for Foxn4, a forkhead transcription factor involved in the genesis of horizontal and amacrine neurons. These data, together with the previous findings on Foxn4, provide a model in which the Foxn4-Ptf1a pathway plays a central role in directing the differentiation of retinal progenitors towards horizontal and amacrine cell fates.

Cadherin is required for dendritic morphogenesis and synaptic terminal organization of retinal horizontal cells.

Dendrite morphology of neurons provides a structural basis for their physiological characteristics, and is precisely regulated in a cell type-dependent manner. Using a unique transposon-mediated gene transfer system that enables conditional and cell-type specific expression of exogenous genes, we investigated the role of cadherin on dendritic morphogenesis of horizontal cells in the developing chicken retina. We first visualized single horizontal cells by overexpressing membrane-targeted EGFP, and confirmed that there were three subtypes of horizontal cells, the dendritic terminals of which projected to distinct synaptic sites in the outer plexiform layer. Expression of a dominant-negative cadherin decreased the dendritic field size, and perturbed the termination of dendritic processes onto the photoreceptor cells. The cadherin blockade also impaired the accumulation of GluR4, a postsynaptic marker, at the cone pedicles. We thus provide in vivo evidence that cadherin is required for dendrite morphogenesis of horizontal cells and subsequent synapse formation with photoreceptor cells in the vertebrate retina.

Knock-down of GFRalpha4 expression by RNA interference affects the development of retinal cell types in three-dimensional histiotypic retinal spheres.

PURPOSE: To determine the role of glial cell line-derived neurotropic factor family receptor alpha 4 (GFRalpha4) during retinogenesis in a three-dimensional histiotypic in vitro model of the embryonic chicken retina. METHODS: Retinal spheres were cultured from dissociated 6-day-old chicken retina under permanent rotation and transfected with GFRalpha4 siRNA at culture day 2. Alterations on proliferation, apoptosis, and differentiation were determined by semiquantitative RT-PCR, in situ hybridization, and immunohistochemistry after 24, 48, and 72 hours. RESULTS: In contrast to control cultures, retinal spheres transfected with GFRalpha4 siRNA showed reduced GFRalpha4 mRNA expression of only 38% after 24 hours, 3% after 48 hours, and 5% after 72 hours. Based on the suppression of GFRalpha4, a decline in proliferating cells from 10% to 4.8% even after 24 hours and a reduction of sphere size by up to 25% at later culture stages were observed. Moreover, the number of Pax 6-positive amacrine, ganglion, and horizontal cells was significantly decreased from 36% to 16% in GFRalpha4 siRNA-transfected retinal spheres 72 hours after transfection. Additionally, GFRalpha4 gene silencing affected the development of different types of photoreceptors, as revealed by a significant decrease of blue opsin mRNA expression from 29% to 2%, whereas green opsin mRNA and the number rho4D2-positive photoreceptors were significantly increased. CONCLUSIONS: These data showed for the first time that GFRalpha4 plays an essential role in regulating, at least in vitro, the development and differentiation of various cell types during retinogenesis.

A non-canonical photopigment, melanopsin, is expressed in the differentiating ganglion, horizontal, and bipolar cells of the chicken retina.

Vertebrate melanopsin is a photopigment in the eye, required for photoentrainment. Melanopsin is more closely related to opsin proteins found in invertebrates, than to the other photo-pigments. Although the invertebrate melanopsin-like protein is localized in rhabdomeric photoreceptors in the invertebrate eye, it has been shown to be expressed in a subset of retinal ganglion cells in the mouse and in horizontal cells in the frog, indicating its diversified expression pattern in vertebrates. Here we show that two types of melanopsin transcripts are expressed in the developing chicken retina. Melanopsin is firstly expressed by a small subset of ganglion cells, and then prominently expressed by horizontal cells and later by bipolar cells in the developing chicken retina. This suggests that a subset of ganglion, horizontal, and bipolar cells in the chicken retina may have rhabdomeric properties in their origins.