Spatial and temporal distribution patterns of enkephalinergic neurons in adult and developing retinas of the preproenkephalin-green fluorescent protein transgenic mouse

Enkephalin (ENK) peptides are present in the retina of several vertebrate species and play a crucial role in establishing specific circuits during retinal development. However, there is no information available concerning the development of ENKergic neurons in the mouse retina. To address this question, we used preproenkephalin-enhanced green fluorescent protein (GFP) transgenic mice, in which ENKergic neurons are revealed by GFP. Our results showed that most GFP-positive cells were located in the proximal part of the inner nuclear layer with a scattering of GFP-immunoreactive cells in the ganglion cell layer (GCL) in the adult retina. Double immunostaining with syntaxin indicates that GFP expression was restricted to a population of amacrine cells. The proportions of glycine transporter-1 and γ-aminobutyric acid-positive cells among ENKergic neurons were 57.3 ± 2.4% and 10.1 ± 1.8%, respectively. We then injected retrograde tracer into the superior colliculus and observed that none of the ENKergic neurons in the GCL were retrogradely labeled with the tracer. GFP-positive cells were first observed at embryonic day (E) 15 in the inner neuroblastic layer at only very low levels, which gradually increased until E18. After birth, there was a steep rise in GFP expression levels, reaching maximal activity by postnatal day (P) 7. The distribution and intensity of GFP-positive cells at P15 were similar to those of adult retina. It was found that immunoreactive processes in the inner plexiform layer formed strongly stained patches. The present results provide detailed morphological evidence of the cell type and spatial and temporal distribution of ENKergic neurons in the retina.     

Substance P-immunoreactive neurons in the retina of two lizards.

The dendritic morphology and retinal distribution of substance P(SP)-immunoreactive neurons was determined in two Australian lizard species Pogona vitticeps and Varanus gouldii, by using immunohistochemistry on retinal wholemounts and sectioned materials. In both species, two classes of SP-immunoreactive neurons were described in the inner nuclear layer (INL) and classified as amacrine cells (types A and B). Type A amacrine cells had large somata and wide-field, bistratified dendrites branching in sublaminas 1 and 5 of the inner plexiform layer (IPL). Their morphology and retinal distribution differed between the two species. Type B amacrine cells in both species had small somata and small-field dendritic branching. A population of SP-immunoreactive neurons with classical ganglion cell morphology were identified in the ganglion cell layer (GCL). Immunostained ganglion cells occurred in larger numbers of Varanus gouldii than in Pogona vitticeps. In both species type B SP cells were the most numerous and were estimated to be about 60,000-70,000. They were distributed non-uniformly with a high density band across the horizontal meridian of the retina, from where the density decreased towards the dorsal and ventral retinal margins. In both species type A amacrine cells occurred in small numbers distributed sparsely in the peripheral retina. The faint immunostaining of SP-immunoreactive neurons in the GCL, did not allow us to reliably determine their numbers and retinal distribution. The functional significance of SP-immunoreactive amacrine and ganglion cells in the lizard retina remains to be determined.     

Expression of Nav1.1 in rat retinal AII amacrine cells

In retinal ganglion cells (RGCs), the expression of various types of voltage-gated sodium channel (Nav) alpha-subunits (Nav1.1, Nav1.2, Nav1.3, and Nav1.6) has been reported. Like RGCs, certain subsets of retinal amacrine cells, including AII amacrine cells, generate tetrodotoxin (TTX)-sensitive action potentials in response to light; however, the Nav subtypes expressed in these cells have not been identified. We examined the Nav subtypes expressed in rat retinal amacrine cells by in situ hybridization (ISH) using RNA probes specific for TTX-sensitive Na(v)s (Nav1.1, Nav1.2, Nav1.3, Nav1.6, and Nav1.7). Our results confirmed that Nav1.1, Nav1.2, Nav1.3, and Nav1.6 are localized in the ganglion cell layer (GCL). Interestingly, Nav1.1 was expressed not only in the GCL, but also in the inner nuclear layer (INL). The cell bodies of the Nav1.1-positive cells in the INL were located at the INL/inner plexiform layer (IPL) border. The cell bodies of AII amacrine cells are located close to the INL/IPL border, and these cells can be labeled with antibodies against parvalbumin (PV). Therefore, we combined ISH with immunohistochemistry and discovered that most of the PV-immunoreactive cells located at the INL/IPL border express Nav1.1. Our results show that AII amacrine cells express Nav1.1.     

Lucifer yellow stains displaced amacrine cells of the chicken retina during embryonic development

We have used Lucifer Yellow for histological tracing of displaced amacrine cells within the ganglion cell layer (GCL) during the embryonic development of the chicken retina. Incubating whole eyes in the dye leads to bright staining of all displaced amacrine cells, whereas ganglion cells and glial cells are not stained. A subpopulation of cells of the inner part of the inner nuclear layer (INL) are also stained (for further details see ref. 13). Kainic acid, which is known to interfere with and kill amacrine cell systems, blocks the staining of these cells fully. This in addition to histological evidence confirms that the LY-stained cells in the GCL are displaced amacrine cells. Of the cells in the GCL, 23% (+/- 3%) are of the displaced amacrine type. Further, we find that the cytoarchitectural arrangement of these cells changes significantly during development.     

Indoleamine-accumulating cell death and endogenous glial cell reaction induced by 5,7-dihydroxytryptamine in the cat retina.

We investigated the patterns of degenerative changes of indoleamine-accumulating cells (IACs) induced by 5,7-dihydroxytryptamine (5,7-DHT, 100 microg), and the glial reaction to the neurodegenerative changes of IACs in the cat retina by using light-and electron-microscopy. The neurons accumulating 5,7-DHT in the cat retina were a few ganglion cells and displaced amacrine cells located in the ganglion cell layer (GCL), and some amacrine cells in the inner nuclear layer (INL). The cell density (per unit area, 1 mm2) of the 5,7-DHT accumulating cells in the GCL and INL was 910 and 134 cells, respectively. Most 5,7-DHT accumulating cells showed dark degeneration characterized by widening of the cellular organelles at early stage, and by darkening of the cytoplasm at a late stage. In addition, amacrine cells, showing a typical filamentous degeneration, were observed in a few cases. The degenerated neurons were phagocytosed by microglial cells and astrocytes. The immunoreactivity for glial fibrillary acidic protein (GFAP) in Muller cells was increased at early stage, but thereafter abruptly decreased. In a few cases, severe degenerative changes were observed in Miller cells. These results indicate that 5,7-DHT induces severe dark degeneration of IACs, and most degenerated cells could be eliminated by microglial cells and astrocytes in the cat retina.     

酒精暴露对视网膜致畸作用和细胞凋亡的影响

目的 探讨产前酒精暴露（PAE）对视网膜致畸作用和细胞凋亡的影响。方法 利用C57BL/6J小鼠建立孕期酒精暴露模型，用HE染色和
免疫荧光染色技术观察酒精对生后0d （P0）、P7、P14和P30 4个年龄点共72只子鼠的视网膜致畸性和细胞凋亡的影响。结果 高剂量酒精组中
视网膜的畸形率增加；在各剂量组Caspase-3、Caspase-8、Caspase-9 阳性细胞于内颗粒层中的表达与在节细胞层中的表达具有一致性，且具
有剂量依赖性(P<0.05)； TUNEL染色结果发现，与对照组相比，酒精组各年龄点的内颗粒层和节细胞层中细胞凋亡量均增加（P<0.05），提示
孕期酒精暴露诱导视网膜细胞发生凋亡时具有长时程效应。结论 视网膜畸形及细胞凋亡可能是导致PAE相关眼病的病理学基础。     

N-methyl-D-aspartate-induced excitotoxicity in adult rat retina is antagonized by single systemic injection of MK-801

Intravitreal injection of N-methyl-D-aspartate (NMDA) produced a substantial damage to the adult rat retina that was largely restricted to inner retinal layers, including the ganglion cell layer (GCL), inner nuclear layer (INL), inner, and outer plexiform layers. This retinal damage was significantly reduced by a systemic injection of a low dose of MK-801 (0.5 mg/kg), a potent NMDA-receptor antagonist. This neuroprotection was dose dependent and was most effective when the antagonist was given 1 h before NMDA insult. An intraperitoneal injection of 0.5 mg/kg MK-801 provided a virtually complete protection to the retina to the NMDA-induced toxicity, as indicated quantitatively by the number of DiI-filled retinal ganglion cells, the number of cells in the GCL and INL that undergo DNA fragmentation, and the edematous changes in retinal thickness. A post-lesion administration of MK-801 was still able to provide an effective neuroprotective effect to the retina, but this protection was lost when MK-801 was given 4 h after NMDA exposure. The current results indicate a therapeutic potential of systemic application of MK-801 in protecting the adult rat retina from neurologic disorders related to excessive activation of NMDA receptors.     

ENK与CaBPs在PPE-GFP转基因小鼠视网膜细胞中的共存

目的:以PPE-GFP转基因小鼠为研究工具,观察绿色荧光蛋白(GFP)阳性的脑啡肽(ENK)能神经元与钙结合蛋白D28K(CB)、钙视网膜蛋白(CR)和小白蛋白(PV)等钙结合蛋白(CaBPs)成员在视网膜的分布及共存情况。方法:利用免疫组织化学和免疫荧光双标染色的方法。结果:GFP阳性的ENK能细胞主要分布在视网膜内核层内缘,少量分布在节细胞层。所有的GFP阳性细胞均与神经元标志物NSE共存,但不与星形胶质细胞标志物GFAP共存。GFP与CB、CR和PV均有部分共存,其中GFP/CB共存神经元占GFP阳性细胞的8.65%,占CB阳性细胞的5.84%;GFP/CR共存神经元占GFP阳性细胞的18.18%,占CR阳性细胞的14.28%,且共存细胞仅见于内核层;GFP/PV共存细胞占GFP阳性细胞的68.75%,占PV阳性细胞的91.67%,共存细胞主要位于内核层,少量见于节细胞层。结论:ENK能神经元在视网膜内具有板层特异性的分布特点和与钙结合蛋白成员有不同的共存模式,上述结果为深入研究小鼠视网膜ENK能神经元的功能意义提供了形态学依据。     

Expression analysis of green fluorescent protein in retinal neurons of four transgenic mouse lines

Transgenic mice that express enhanced green fluorescent protein (EGFP) under the control of a cell-specific promoter have been used with great success to identify and label specific cell types of the retina. We studied the expression of EGFP in the retina of mice making use of four transgenic mouse lines. Expression of EGFP driven by the calretinin promoter was found in amacrine, displaced amacrine and ganglion cells. Comparison of the EGFP expression and calretinin immunolabeling showed that many but not all cells appear to be double labeled. Expression of EGFP under the control of the choline acetyltransferase promoter was found in amacrine cells; however, the cells did not correspond to the well known cholinergic (starburst) cells of the mouse retina. The expression of EGFP under the control of the parvalbumin promoter was restricted to amacrine cells of the inner nuclear layer and to cells of the ganglion cell layer (displaced amacrine cells and ganglion cells). Most of the cells were also immunoreactive for parvalbumin, however, differences in labeling intensity were observed. The expression of EGFP driven by the promoter for the 5-HT3 A receptor (5-HTR3A) was restricted to type 5 bipolar cells. In contrast, immunostaining for 5-HTR3A was found in synaptic hot spots in sublamina 1 of the inner plexiform layer and was not related to type 5 bipolar cells. The results show that these transgenic mice are very useful for future electrophysiological studies of specific types of amacrine and bipolar cells that express EGFP and thus permit directed microelectrode targeting under microscopic control.     

GABA_A和GABA_C受体各亚单位基因在鲫鱼视网膜内的分布──原位杂交组织化学法研究

应用原位杂交组织化学技术，利用同位素［￣（３５）Ｓ］－ｄＡＴＰ标记的寡核苷酸探针，在鲫鱼视网膜观察了含ＧＡＢＡＡ受体α１、α３、α４、α６，β１－３，γ１－２及ＧＡＢＡＣ受体ρ１亚单位ｍＲＮＡ的神经元分布。在外核层，所有测试的亚单位均无表达；而在内核层和神经节细胞层，除α４和γ２亚单位外，均有不同程度的表达。在不同区域标记神经元的数量和标记强度各不相同，α１亚单位广泛分布在内核层的远端、中部及神经节细胞层，呈强阳性；α３亚单位相对稀少，主要分布在内核层近端和神经节细胞层，呈中等阳性；α４和α６亚单位几乎无阳性表达，仅α６亚单位在神经节细胞层呈弱阳性。β１和β２亚单位在内核层及神经节细胞层呈中等阳性；β３亚单位主要分布在内核层，在神经节细胞层标记细胞较少，呈弱阳性。γ１亚单位分布在整个内核层，在神经节细胞层有零星阳性表达。ＧＡＢＡＣ受体主要分布在内核层，ρ１亚单位主要分布在内核层的远端及中间部分，呈强阳性，而在神经节细胞层表达相对较弱。这种独特的表达型式与其功能密切相关。     

Glutamate receptor expression in the rat retina.

The expression of five genes (GluR A; B; C; D; GluR 5) encoding functional subunits of glutamate receptors was investigated in the rat retina using in situ hybridization with oligonucleotide probes. All five genes are expressed in the retina. All probes label cell bodies in the ganglion cell layer as well as somata in the inner third of the inner nuclear layer (INL), where the amacrine cells are located. In addition GluR 5, B and D, and to a lesser extent also GluR A are found in the middle and outer part of the INL, where bipolar and horizontal cells reside. Different subsets of retinal neurons may thus use glutamate receptors of different subunit composition.     

Increased expression of ciliary neurotrophic factor receptor alpha mRNA in the ischemic rat retina

Using in situ hybridization, we investigated the expression of ciliary neurotrophic factor receptor ((CNTFRalpha) mRNA in the rat retina rendered ischemic by elevation of the intraocular pressure (IOP). The IOP was increased to 120 mmHg and maintained for 60 min. The rats were sacrificed on the day of reperfusion (DRP) 1, 3, 7, 14, and 28. In the normal retina, the signal for CNTFRalpha mRNA was present in retinal cells in the inner nuclear layer (INL) and in the ganglion cell layer (GCL). On DRP 1, numerous cells in the INL and GCL showed a CNTFRalpha mRNA signal. From DRP 3 onwards, CNTFRalpha mRNA appeared in photoreceptor cells located in the outer part of the outer nuclear layer. The signal in these cells increased up to DRP 14 and then decreased at DRP 28. Our findings suggest that cells expressing CNTFRalpha mRNA may resist the degenerative processes induced by ischemic insult in the rat retina.     

Enhanced protein expressions of sortilin and p75NTR in retina of rat following elevated intraocular pressure-induced retinal ischemia

Elevated introcular pressure (IOP)-induced retinal neuron ischemic death includes an early phase of necrosis and prolonged phase of apoptosis. We used this ischemic model to observe the changes of sortilin and p75(NTR) protein expressions in rat retina. The results of Western blot analysis showed the expression of p75(NTR) at the band of 75 (mature form), 60 (non-glycosylated pieces) and 50 kDa (ectodomain shedding pieces), and the expression of sortilin at the 95 and 90 kDa (the mature form). The protein expressions of p75(NTR) (60 and 50 kDa pieces) and sortilin (90 kDa) increased significantly (p < 0.05) at days 3, 5 and 7 after retinal ischemia. This effect was also confirmed by immunofluorescence staining. Sortilin was primarily present in cell membrane of the ganglion cells layer (GCL) and large ganglion cell bodies by immunofluorescence labeling. There was little expression of p75(NTR) in the normal retina, while expression increased extensively in GCL, inner plexiform layer (IPL) and inner nuclear layer (INL) after retinal ischemia. p75(NTR) was shown to co-localize with neurofilament in the axons of neuronal cells by double-labeling. These results suggested that the protein expressions of 60 and 50 kDa forms of p75(NTR), and the 90 kDa mature form of sortilin increased in ischemia-induced retinal neuron of rats.     

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。     

Müller细胞反应性胶质化在急性高眼压致大鼠视网膜损伤中作用

 目的 观察Müller细胞反应性胶质化在急性高眼压(AOH)大鼠视网膜中变化及其抑制对视网膜损伤的影响。方法 建立大鼠AOH青光眼模型,分为正常对照(Ctrl)、AOH和AOH+玻璃体内注射胶质毒素α-氨基己二酸(AAA)后再灌注1、3和5d组,以及单纯AAA和AOH+PBS对照组。TUNEL染色检测细胞凋亡,GFAP免疫荧光染色反应Müller细胞反应性胶质化程度,Thy-1染色标记视网膜神经节细胞(RGCs)。结果 AOH可致大鼠视网膜内丛状层和内核层明显变薄、神经节细胞层内细胞排列紊乱和数量减少,并诱发Müller细胞反应性胶质化(GFAP表达增加)。同时,AAA抑制Müller细胞反应性胶质化可明显缓解AOH所致RGCs丢失和凋亡发生。结论 Müller细胞反应性胶质化参与AOH所致视网膜损伤,抑制其反应性胶质化可能是改善高眼压性青光眼视网膜病变的一种有效治疗方法。     

Identification and characterization of SMI32-immunoreactive amacrine cells in the mouse retina

Mammalian neurons express the neural intermediate filament protein neurofilament (NF). In the retina, NFs have been detected primarily in the axons and processes of retinal ganglion and horizontal cells. We found an amacrine cell type that was immunolabeled with an antibody against SMI32, a non-phosphorylated epitope on neurofilament proteins of high molecular weight, in the mouse retina. This type of amacrine cell was non-randomly distributed, and these cells exhibited a central-peripheral density gradient. Most of these cells co-expressed GABA and ChAT, but not glycine or any other amacrine cell marker. These results suggest that some SMI32-immunoreactive amacrine cells belong to a GABAergic population, and that SMI32 can therefore be used as a marker for a subset of amacrine cells in addition to ganglion cells and horizontal cells in the mouse retina.     

Distribution of GABA immunoreactivity in kainic acid-treated rabbit retina

Ischaemic retinal cell degeneration seems to involve both NMDA and non-NMDA receptor over stimulation. However, different retinal cell types differ largely in their susceptibility to excitatory amino acid induced neurotoxicity. We have investigated the vulnerability of GABAergic cells in the rabbit retina to the non-NMDA receptor agonist kainic acid (KA). The distribution of GABA immunoreactivity (GABA-IR) was examined in the central inferior retina at different survival times (5 h–6 days) following an intra-ocular injection of 140 nmol KA and compared to that of control and untreated retinas. In the normal retina, the majority of GABA-positive cells (79%) were located in the inner nuclear layer (INL), in one to four cell rows next to the inner plexiform layer (IPL), and in one cell row next to the outer plexiform layer (OPL). The remainder (21%) were found in the ganglion cell layer (GCL). Dense immunoreactivity was seen throughout the IPL. In the OPL, stained dots and occasional immunoreactive large processes could be seen. KA-exposed retinas processed for GABA immunocytochemistry 5 and 24 h after the injection showed an 85% reduction in the number of GABA immunoreactive cells. About the same degree of depletion was seen among GABA-IR cells located at different retinal levels. However, at these survival times, immunostaining was observed in three distinct bands in the IPL, indicating that the vulnerability to KA is not uniformly distributed among all GABAergic cells. At 48 h, an additional decrease in the number of labelled cells was noted, but immunoreactive cells were still found both in the INL and GCL. Even 6 days after KA treatment, a few stained cell bodies were seen in the INL next to the IPL, as well as a few processes in the IPL. The study shows that KA receptor overstimulation induces a marked depletion of the endogenous cellular GABA pools of the central rabbit retina, most likely as a result of GABAergic cell loss. However, a small population of GABAergic cells located in the INL appears to be less vulnerable to the toxic effects of 140 nmol KA.     

Morphological properties of mouse retinal ganglion cells

The mouse retina offers an increasingly valuable model for vision research given the possibilities for genetic manipulation. Here we assess how the structural properties of mouse retinal ganglion cells relate to the stratification pattern of the dendrites of these neurons within the inner plexiform layer. For this purpose, we used 14 morphological measures to classify mouse retinal ganglion cells parametrically into different clusters. Retinal ganglion cells were labeled in one of three ways: Lucifer Yellow injection, 'DiOlistics' or transgenic expression of yellow fluorescent protein. The resulting analysis of 182 cells revealed 10 clusters of monostratified cells, with dendrites confined to either On or Off sublaminae of the inner plexiform layer, and four clusters of bistratified cells, dendrites spanning the On and Off sublaminae. We also sought to establish how these parametrically identified retinal ganglion cell clusters relate to cell types identified previously on the basis of immunocytochemical staining and the expression of yellow fluorescent protein. Cells labeled with an antibody against melanopsin were found to be located within a single cluster, while those labeled with the SMI-32 antibody were in four different clusters. Yellow fluorescent protein expressing cells were distributed within 13 of the 14 clusters identified here, which demonstrates that yellow fluorescent protein expression is a useful method for labeling virtually the entire population of mouse retinal ganglion cells. Collectively, these findings provide a valuable baseline for future studies dealing with the effects of genetic mutations on the morphological development of these neurons.     

Spatial and temporal patterns of apoptosis during differentiation of the retina in the turtle

We investigated patterns of cell death in the turtle retina that could potentially be associated with the innervation of the optic tectum, and looked for mechanisms of retinal development that might be common to reptilian and homeotherm vertebrates. We used retinas of turtle embryos between the 23rd day of incubation (E23) (before the first optic fibres reach the optic tectum) and hatching (when all the optic fibres have established synaptic connections). Dying retinal neurons were identified in paraffin sections by the TUNEL technique, which specifically labels fragmented DNA. Apoptotic cells were found in the ganglion cell layer (GCL), the inner nuclear layer (INL), and the outer nuclear layer (ONL). Cell death in the GCL was intense between E29 and E47, and had disappeared by the day of hatching. In the INL, dead and dying cells were most abundant between E31 and E34, and progressively disappeared. The temporal pattern in the ONL was similar to the INL although the density was very low. In all the nuclear layers cell death spread from the dorso-temporal area of the central retina to the periphery. Additional dorsal to ventral and temporal to nasal gradients were distinguishable in a quantitative TUNEL analysis. The patterns of cell death observed in the developing turtle retina were thus similar to those found in birds and mammals. This process could be under the control of differentiation gradients in all the vertebrate classes.