Generation of retinal cells in the wallaby, Setonix brachyurus (quokka)

We have examined the generation of retinal cells in the wallaby, Setonix brachyurus (quokka). Animals received a single injection of tritiated thymidine between postnatal days 1-85 and retinae were examined at postnatal day 100. Retinae were sectioned, processed for autoradiography and stained with Cresyl Violet. Ganglion cells were labelled by injection of horseradish peroxidase into the optic tracts and primary visual centres. Other cells were classified according to their morphology and location. Retinal cell generation takes place in two phases. During the first phase, which concludes by postnatal day 30, cells destined to lie in all three cellular layers of the retina are produced. In the second phase, which starts by postnatal day 50, cell generation is almost entirely restricted to the inner and outer nuclear layers. Cells produced in the first phase are orthotopic and displaced ganglion cells, displaced and orthotopic amacrine cells, horizontal cells and cones. Glia in the ganglion cell layer, orthotopic amacrine cells, bipolar and horizontal cells. Muller glia, and rods are generated in the second phase. Cells became heavily labelled with tritiated thymidine in the central retina before postnatal day 7, over the entire retina (panretinal) by postnatal day 7 and from postnatal day 18, only in the periphery. The second phase of cell generation is initiated at P50, in a region extending from the optic nerve head to mid-temporal retina. Subsequently, cells are generated in annuli, centred on mid-temporal retina, which are seen at progressively more peripheral locations. Therefore, cell addition to the inner and outer nuclear layers continues for longer in peripheral than in mid-temporal retina. We suggest that such later differential cell addition to the inner and outer nuclear layers contributes to an asymmetric increase in retinal area. This non-uniform growth presumably results in more expansion of the ganglion cell layer peripherally than in mid-temporal retina and may play a role in establishing density gradients of ganglion cells.     

大鼠视神经切断后视网膜双极细胞PKC-α和recoverin的表达

为了探讨视神经切断后视网膜内部是否存在突触可塑性改变,本实验采用大鼠视神经切断模型,通过免疫组织化学方法检测视神经切断后视网膜双极细胞PKC-α和recoverin的表达变化。结果显示:正常视网膜中,PKC-α和recoverin阳性产物主要见于视网膜内核层、内网层及节细胞层,另外外核层也可见少量recoverin阳性细胞。视神经切断后3d,大鼠视网膜内网层高倍镜下可见PKC-α和recoverin免疫阳性终末的数量开始增加,14d时增至最高,21d、28d呈现逐渐减少的趋势。本研究结果提示视神经切断后视网膜双极细胞与节细胞之间的突触可能存在早期增生,后期溃变的可塑性变化。     

Synapsin I expression in the rat retina during postnatal development

Summary The expression of the synapsin I gene was studied during postnatal development of the rat retina at the mRNA and protein levels. In situ hybridization histochemistry showed that synapsin I mRNA was expressed already in nerve cells in the ganglion cell layer of the neonatal retina, while it appeared in neurons of the inner nuclear layer from postnatal day 4 onward. Maximal expression of synapsin I mRNA was observed at P12 in ganglion cells and in neurons of the inner nuclear layer followed by moderate expression in the adult. At the protein level a shift of synapsin I appearance was observed from cytoplasmic to terminal localization during retinal development by immunohistochemistry. In early stages (P4 and P8), synapsin I was seen in neurons of the ganglion cell layer and in neurons of the developing inner nuclear layer as well as in the developing inner plexiform layer. In the developing outer plexiform layer synapsin I was localized only in horizontal cells and in their processes. Its early appearance at P4 indicated the early maturation of this cell type. A shift and strong increase of labelling to the plexiform layers at P12 indicated the localization of synapsin I in synaptic terminals. The inner plexiform layer exhibited a characteristic stratified pattern. Photoreceptor cells never exhibited synapsin I mRNA or synapsin I protein throughout development.Abbreviations GCL ganglion cell layer - INB inner neuroblast layer - INL inner nuclear layer - IPL inner plexiform layer - ONB outer neuroblast layer - ONL outer nuclear layer - OPL outer plexiform layer     

高血压大鼠视网膜溶酶体酶组织化学研究

目的：探讨溶酶体酶在高血压视网膜网变发生过程中的作用。方法：应用光镜定量酶组织化学方法对ＷＫＹ大鼠和自发性高血压大鼠视网膜原酸性磷酸的分布和活性变化进行定量观察。结果：视网膜各层酸性磷酸酶活性岂强到弱依次是（Ｆ检验，Ｐ〈０．０５）；（１）色素上皮层；（２）视杆维层内节和外网层（两层间活性无显著性差异）；（３）内网层；（４）节细胞层和神经纤维层，（５）外核层和内核层（两层间活性无显著性差异）杆锥层外     

The development of the retina of the albino rat

Morphogenesis of the retina of the Sprague-Dawley albino rat was studied by light microscopy from day 11 of gestation until 225 days after birth. A quantitative analysis during development of retinal volume, thickness of the entire neural retina and thickness of each of the retinal layers, both posteriorly and peripherally, was made. The results indicate that initially a single neuroblastic layer forms and continually thickens by mitosis at its outer border. The retinal layers then form in sequence, moving from the inner retinal border outward and always beginning posteriorly and then spreading peripherally. The transient layer of Chievitz does not appear. All adult layers are present by eight days after birth and each layer thins after reaching its maximal thickness. Total thickness of the retina excluding pigmented epithelium, is greatest on postnatal day 5, but retinal volume only reaches a peak on postnatal days 7 to 12. The nerve fiber, inner plexiform, outer plexiform and bacillary layers all continue to increase in thickness after the ganglion cell and inner and outer nuclear layers reach their maximal width and are beginning to become thinner.     

Retinal histogenesis and cell differentiation in an elasmobranch species, the small-spotted catshark Scyliorhinus canicula

Here we present a detailed study of the major events in the retinal histogenesis in a slow-developing elasmobranch species, the small-spotted catshark, during embryonic, postnatal and adult stages using classical histological and immunohistological methods, providing a complete neurochemical characterization of retinal cells. We found that the retina of the small-spotted catshark was fully differentiated prior to birth. The major developmental events in retinal cell differentiation occurred during the second third of the embryonic period. Maturational features described in the present study were first detected in the central retina and, as development progressed, they spread to the rest of the retina following a central-to-peripheral gradient. While the formation of both plexiform layers occurs simultaneously in the retina of the most common fish models, in the small-spotted catshark retina the emergence of the outer plexiform layer was delayed with respect to the inner plexiform layer. According to the expression of the markers used, retinal cell differentiation followed a vitreal-to-scleral gradient, with the exception of Müller cells that were the last cell type generated during retinogenesis. This vitreal-to-scleral progression of neural differentiation seems to be specific to slow-developing fish species.     

人胎视网膜发生的光镜和电镜观察

本文在光镜下观察40例人胎视网膜的发生,在电镜下观察15例人胎视网膜视细胞、双极细胞、节细胞的发育。结果表明:胚胎第9周时神经上皮可分内、外成神经细胞层。第10周时内、外成神经细胞层之间的Chievitz带消失;第11周时节细胞从内成神经细胞层内迁;第13周节细胞与内成神经细胞之间出现内网层;第16周始双极细胞从外成神经细胞层中内迁形成外网层和内核层。第20周后视网膜各层形成。而视细胞、双极细胞、节细胞的超微结构于胎儿8个月后才发育完善。其结构与成人基本相同。     

In utero development and maturation of the retina of a non-primate mammal: A light and electron microscopic study of the guinea pig

Summary A light and electron microscopic examination of retinogenesis in the fetal guinea pig has revealed an early development of synapses and photoreceptor cells. Differentiation of the neural retina begins around day 23 of gestation. By 34 days the retina reaches its maximum thickness. It differentiates an inner plexiform layer in which vesicle-containing processes and primitive synapses are evident. Synaptic ribbons are found in processes of this layer by 43–45 days of gestation. An outer plexiform layer develops within the neuroblast layer at 40 days of gestation; from its first appearance the outer plexiform layer contains synapses complete with synaptic ribbons. Receptor terminals of the , paranuclear and type are present well before birth. Photoreceptor cells form inner segments by 40 days; the formation of outer segments is indicated by 45 days but not widespread until 49 days. The retina appears mature by day 51–57. It is clear that the primate is not unique in the early differentiation of its retinal synapses relative to the time of maturation of its photoreceptor cells. The potential functional capacities of precocious retinae, and the mechanisms of synapse development are discussed.Supported by Grants from the Medical Research Council.     

Somatostatin-like immunoreactive material in associational ganglion cells of human retina

The retinal ganglion cell is classically viewed as the output cell of the retina, sending a single axon via the optic nerve to synapse in visual relay nuclei of the brain. However, some ganglion cells, termed associational ganglion cells, have axons which do not leave the retina and presumably serve intraretinal communication. Using high-affinity and specific monoclonal antibodies to somatostatin-14 and the avidin-biotin-peroxidase immunohistochemical procedure, somatostatin-immunoreactive associational ganglion cells are specifically stained in human retinas obtained at necropsy. These cells are more numerous in the inferior than the superior retina; they have dendrites which ramify in the inner plexiform layer; and they have sparsely branching axons, many of which can be traced over 1 cm. These axons do not enter the optic nerve. They follow remarkably straight courses at the border of the inner plexiform layer and ganglion cell layer and thereby form a gridwork of fibers covering the entire retinal area. These observations verify the existence of associational ganglion cells in the human and establish somatostatin as a neurotransmitter or neuromodulator candidate for these neurons. The morphology of these cells suggests that they are involved in long-distance interactions within the retina.     

Lamina formation in the Mongolian gerbil retina (Meriones unguiculatus)

Retinae of nocturnal rodents, such as mice and rats, are almost exclusively rod-dominated. The gerbil, in contrast, shows active periods during day and night and uses both rod- and cone-based vision. However, its retina has not been studied in detail, except for one developmental study analysing its prenatal period (Wikler et al. 1989). Here, the formation of the laminar structure of the gerbil retina was studied from birth until late adult stages. At birth, the retina consisted of a wide neuroblastic layer, with 30% of cells still dividing, a rate decreasing to nearly zero by P6. Shortly after birth, segregation of a ganglion cell layer began. All retinal layers reached their final size around P20, as determined from DAPI-stained cryosections. Müller glial cells developed their typical structure from P1 onwards, e.g. announcing an outer plexiform layer (OPL) at P5, as analysed by the Ret-G7 and glutamine synthetase antibodies. The analyses of the inner retina were performed by antibodies to calretinin (CR) and calbindin (CB). CR is expressed in ganglion cells followed by amacrine cells from P1 onwards; their processes formed four subbands in the inner plexiform layer (IPL) and appeared sequentially after P5 until P20. CB stained a subtype of horizontal cells with their processes into the OPL from P14 onwards. The rod-specific antibody rho4D2 announced photoreceptors at P4, showing signs of outer segments from P10 onwards. The study shows that the formation of all retinal layers in the gerbil occurs postnatally. This and the fact that the gerbil retina is not exclusively rod-dominated could render the gerbil a valuable model for in vitro studies of retinogenesis in rodents.     

钠尿肽受体A在小鼠视网膜发育过程中的表达

目的检测钠尿肽受体(NPR)在不同年龄小鼠视网膜内的表达,探讨其在视网膜发育过程中的作用。方法收集从受孕16日(E16)到出生90日(P90)小鼠眼球标本共127只,对NPR-A进行免疫荧光检测。结果NPR-A广泛存在于视网膜神经元中,例如,在外核层,NPR-A于P7开始高表达在视锥、视杆细胞内、外突起上,于P14减弱,P30之后持续稳定弱表达;在内核层,从P7开始NPR-A持续弱表达在双极细胞的突起中,而在水平细胞中未见NPR-A表达;在神经节细胞层,NPR-A于E16开始高表达在神经节细胞胞体中,P14明显减弱,而在神经纤维层,即神经节细胞的轴突中,NPR-A从胚胎期至成年持续高表达;在外网状层和内网状层,NPR-A于P14均高表达,但于P30之后逐渐减弱。此外,NPR-A还广泛的存在于Müller细胞的突起中。结论 NPR-A参与了视网膜的发育,可能是小鼠视网膜神经元发育过程中的关键分子,并对Müller细胞的功能活动起着重要的调节作用。     

Morphology and retinal distribution of tyrosine hydroxylase-like immunoreactive amacrine cells in the retina of developingXenopus laevis

Summary The development of neurons immunoreactive to tyrosine hydroxylase (TH-IR) in the retina ofXenopus laevis was investigated from stage 53 tadpoles to adult, by using an antibody against tyrosine hydroxylase. At all developmental stages, most of the immunoreactive somata were located in the inner nuclear layer, and a few in the ganglion cell layer. Immunoreactive processes arborised in the scleral and vitreal sublaminae of the inner plexiform layer, indicating that these cells were bistratified amacrine cells. However, occasionally a few immunoreactive processes were observed projecting to the outer plexiform layer, suggesting the presence of THIR interplexiform cells. The number of immunoreactive amacrine cells in the inner nuclear layer per retina increased from 204 at stage 53 tadpole to 735 in adult, while the number of immunoreactive amacrine cells in the ganglion cell layer did not change significantly over the same period. Retinal area increased from 1.95 mm² at stage 53 to 23.40 mm² in the adult, and correspondingly cell density in the inner nuclear layer decreased from 104/mm² to 31/mm². At all stages there was an increasing density towards the ciliary margin, but this gradient decreased with age. The soma size of immunoreactive amacrine cells increased with age, and was consistently larger in the central than in the peripheral retina. Dendritic field size was estimated to increase 13-fold, from stage 53 to adult. This study shows that tyrosine hydroxylase-like immunoreactive amacrine cells are generated continuously throughout life, that after metamorphosis the retina grows more by stretching than by cell generation at the ciliary margin, and that the increase of dendritic field size is proportional to the increase in retinal surface area.On leave from Department of Anatomy, Zhanjiang Medical College, Guangdong, People's Republic of China     

高血压大鼠视网膜组织Ca^2＋酸性磷酸酶组织化学的研究

目的：应用光镜定量酶组织化学方法对正常京都种大鼠（ＷＫＹ）和自发性高血压大鼠（ＳＨＲ）视网膜组织的Ｃａ＾２＋－酸性磷酸酶的分布和活性进行定量观察，结果：Ｃａ＾２＋酸性磷酸酶在ＷＫＹ视网膜组织的活性由强到弱依次为（Ｆ检验，Ｐ〈０．０５）；（１）杆锥细胞内节和外核层；（２）节细胞层；（３）内核层；（４）内网层和外网层；（５）杆锥细胞外节阴性，在ＳＨＲ视网膜组织中，各层Ｃａｓ＾２＋酸性磷酸酶活性下降，以     

Histology of the ferret retina

The retina of the adult ferret, Mustelo furo, was studied with light and transmission electron microscopy to provide an anatomical basis for use of the ferret as a model for retinal research. The pigment epithelium is a simple cuboidal layer of cells characterized by a zone of basal folds, apical microvilli, and pigment granules at various stages of maturation. The distinction between rod and cone photoreceptor cells is based on their location, morphology, heterochromatin pattern and the electron density of their inner segments. The round, light-staining cone cell nuclei occupy the layer of perikarya along the apical border of the outer nuclear layer. The remainder of the outer nuclear layer consists of oblong, deeply-stained rod cell nuclei. Ribbon type synaptic complexes involving photoreceptor cell axons, horizontal cell processes, and bipolar cell dendrites characterize the outer plexiform layer. The inner nuclear layer is comprised of horizontal, bipolar, and amacrine cell perikarya as well as the perikarya of the Müller cells. The light-staining horizontal cell nuclei are prominent along the apical border of the inner nuclear layer. The light-staining amacrine cell nuclei form a more or less continuous layer along the basal border of the inner nuclear layer. Both conventional and ribbon-type synapses characterize the inner plexiform layer. The ganglion cells form a single cell layer. The optic fiber layer contains bundles of axons surrounded by Müller cell processes. Small blood vessels and capillaries are present in the basal portion of the retina throughout the region extending from the internal limiting membrane to the outer plexiform layer. The adult one-year-old retina is compared with the retina at the time of eye opening.     

Lamina formation in the Mongolian gerbil retina (<Emphasis Type="Italic">Meriones unguiculatus</Emphasis>)

Retinae of nocturnal rodents, such as mice and rats, are almost exclusively rod-dominated. The gerbil, in contrast, shows active periods during day and night and uses both rod- and cone-based vision. However, its retina has not been studied in detail, except for one developmental study analysing its prenatal period (Wikler et al. 1989). Here, the formation of the laminar structure of the gerbil retina was studied from birth until late adult stages. At birth, the retina consisted of a wide neuroblastic layer, with 30% of cells still dividing, a rate decreasing to nearly zero by P6. Shortly after birth, segregation of a ganglion cell layer began. All retinal layers reached their final size around P20, as determined from DAPI-stained cryosections. Müller glial cells developed their typical structure from P1 onwards, e.g. announcing an outer plexiform layer (OPL) at P5, as analysed by the Ret-G7 and glutamine synthetase antibodies. The analyses of the inner retina were performed by antibodies to calretinin (CR) and calbindin (CB). CR is expressed in ganglion cells followed by amacrine cells from P1 onwards; their processes formed four subbands in the inner plexiform layer (IPL) and appeared sequentially after P5 until P20. CB stained a subtype of horizontal cells with their processes into the OPL from P14 onwards. The rod-specific antibody rho4D2 announced photoreceptors at P4, showing signs of outer segments from P10 onwards. The study shows that the formation of all retinal layers in the gerbil occurs postnatally. This and the fact that the gerbil retina is not exclusively rod-dominated could render the gerbil a valuable model for in vitro studies of retinogenesis in rodents.     

Expression of Glutamate and GABA during the Process of Rat Retinal Synaptic Plasticity Induced by Acute High Intraocular Pressure

Acute high intraocular pressure (HIOP) can induce plastic changes of retinal synapses during which the expression of the presynaptic marker synaptophysin (SYN) has a distinct spatiotemporal pattern from the inner plexiform layer to the outer plexiform layer. We identified the types of neurotransmitters in the retina that participated in this process and determined the response of these neurotransmitters to HIOP induction. The model of acute HIOP was established by injecting normal saline into the anterior chamber of the rat eye. We found that the number of glutamate-positive cells increased successively from the inner part to the outer part of the retina (from the ganglion cell layer to the inner nuclear layer to the outer nuclear layer) after HIOP, which was similar to the spatiotemporal pattern of SYN expression (internally to externally) following HIOP. However, the distribution and intensity of GABA immunoreactivity in the retina did not change significantly at different survival time post injury and had no direct correlation with SYN expression. Our results suggested that the excitatory neurotransmitter glutamate might participate in the plastic process of retinal synapses following acute HIOP, but no evidence was found for the role of the inhibitory neurotransmitter GABA.     

An ultrastructural analysis of the development of foetal rat retina transplanted to the occipital cortex, a site lacking appropriate target neurons for optic fibres

Summary Foetal retina was removed from donor rats at 15 days of gestation and transplanted to the occipital cortex of neonatal host rats. The purpose of this procedure was to examine the development of retinal neurons and photoreceptors, and document synaptic patterns during maturation of the transplanted retina in an environment lacking a normal target for optic axons. Host animals were sacrificed at 5, 10, 15, 20 and 30 days and samples of cortex containing the transplant were subjected to a light and electron microscopic analysis. During early stages of development, (5 days) the retina assumes a radial orientation with the scleral (outer) surface located centrally and the vitreal (inner) surface occupying the periphery. Numerous mitotic figures are found at the centre of the transplant and columns of primitive neuroblasts appear to radiate out from this zone. By 10 to 15 days after transplantation the retinal tissue contains numerous small rosettes each of which displays a histotypic organization with recognizable layers of sensory cells and their centrally-projecting processes, an outer limiting membrane, made up of a network of zonulae adherentes, and a rudimentary outer and inner plexiform layer which delineate the cells of the inner nuclear layer. Ultrastructural analysis of such rosettes confirmed the presence of typical bipolar, amacrine, horizontal and ganglion cells, but revealed that while the plexiform layers were occupied by numerous processes from these neurons, few if any, of these exhibited synaptic vesicles.By 20 to 30 days following transplantation sensory cells have completely differentiated, giving rise to prominent inner and outer segments which display typical cilia, centrioles and basal bodies, together with numerous stacked lamellae of photoreceptors which were contorted, presumably due to growth in an abnormal site. It should be further emphasized that these structures developed in the absence of pigment cells. Synaptic development ensues during this period to form characteristic dyads within the outer and inner plexiform layers. Additionally, clusters of amacrine to amacrine contacts occurred in the inner plexiform layer and were found to be increased relative to other types of junctions. In general, synaptogenesis takes place in the outer and inner plexiform layers and all categories of retinal synapses are established, but the process was found to be significantly delayed in comparison to normal retina at the same stage of development.Quantitative analysis revealed a reduced number of presumptive ganglion cells in proportion to the other categories of neurons. Optic fibres remained small and failed to myelinate. It is suggested that lack of an appropriate target for optic axons induced this alteration and may be indirectly related to the delay in the onset of synaptic development.     

Cholinergic amacrine cells of the chicken retina: a light and electron microscope immunocytochemical study

Cholinergic amacrine cells of the chicken retina were detected by immunohistochemistry using an antiserum against affinity-purified chicken choline acetyltransferase. Three populations of cells were detected: type I cholinergic amacrine cells had cell bodies on the border of the inner nuclear and inner plexiform layers and formed a prominent laminar band in sublamina 2 of the inner plexiform layer, while type II cholinergic amacrine cells had cell bodies in the ganglion cell layer, and formed a prominent laminar band in sublamina 4 of the inner plexiform layer. Type III cholinergic amacrine cell bodies were located towards the middle of the inner nuclear layer, and their processes were more diffusely distributed in sublaminas 1 and 3-5 of the inner plexiform layer. Type I and type II cells were present at densities of over 7000 cells/mm2 in central areas declining to less than 2000 cells/mm2 in the temporal retinal periphery. The cells were organized locally in a non-random mosaic, with regularity indices ranging from 3 peripherally to over 5 centrally. Neither at the light nor electron microscopic levels was a lattice of cholinergic dendrites of the kind reported by Tauchi and Masland [J. Neurosci. 5, 2494-2501 (1985)] detectable. Within the two prominent dendritic plexuses, a major feature of the synaptic interactions of the type I and type II cholinergic cells was extensive synaptic interaction between cholinergic processes. Apart from this, there was little, if any, input to cholinergic processes from non-cholinergic amacrine cells, but there was input from bipolar cells. Output from the cholinergic amacrine cell processes was directed towards non-cholinergic amacrine cells as well as other cholinergic amacrine cells, and ganglion cells.