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。     

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     

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.     

兔视网膜中P物质样免疫反应神经元的发育

本实验用免疫细胞化学ABC法,研究了成年、新生和生后兔视网膜中P物质(SP)样免疫反应神经元的定位和发育。结果表明,成年兔视网膜SP样免疫反应细胞胞体位于内核层和节细胞层,胞突分布在内网层的第1、3、5亚层,偶见于视神经纤维层。细胞密度以视纹最高,从视纹向背腹视网膜边缘区密度渐变小。在新生兔视网膜已有SP阳性胞体和胞突出现,胞体主要位于节细胞层,突起在内网层第5亚层,但未形成连续网层,在第1亚层很少,第3亚层未见SP阳性突起。SP阳性细胞密度从新生到生后第4天增加,生后第6天到第12天细胞密度渐下降。生后第12天SP阳性胞体主要位于内核层。生后第20天,SP阳性细胞的形态、密度与分布已接近成年水平。上述结果提示,在兔视网膜中SP样免疫反应胞体和突起在生前已出现,生后继续发育,到生后20天后其形态发育已接近成熟。     

SUN N8075, a novel radical scavenger, protects against retinal cell death in mice

In this study, we examined the effect of SUN N8075, a radical scavenger with neuroprotective properties, on murine retinal damage induced by intravitreous injection of N-methyl-d-aspartate (NMDA) or high-intraocular pressure (IOP). In both models, systemic administration of SUN N8075 decreased the cell loss in the ganglion cell layer (GCL) after retinal damage occurred. Moreover, SUN N8075 reduced the number of apoptotic cells and the expression of an oxidative stress marker in GCL in the NMDA model. These findings suggest that SUN N8075 has a neuroprotective effect against retinal damage, presumably via the radical scavenging effect.     

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.     

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.     

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。     

Retinal blood vessels are damaged in a rat model of NMDA-induced retinal degeneration

Retinal ischemia–reperfusion causes capillary degeneration but the mechanisms of damage are not well understood. The NMDA receptor plays an important role in neuronal damage after ischemia–reperfusion. Therefore, we determined whether retinal blood vessels are damaged structurally and functionally in a rat model of retinal degeneration induced by NMDA. At 7 days after a single intravitreal injection of NMDA (200 nmol) into the eye, loss of retinal ganglion cells and thinning of the inner plexiform layer were observed. Endothelial cells disappeared in some regressing vessels and empty basement membrane sleeves were left as remnants of the vessels. The number of basement membrane sleeves was increased in the NMDA-treated retina and non-perfused vessels were found in the injured retina. These results indicate that retinal blood vessels are damaged in the NMDA-induced retinal degeneration model. Neuronal cells may play a role in maintaining normal structure and function of the vasculature 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.     

泛素蛋白酶系统在四氧嘧啶诱导的糖尿病大鼠视网膜中的表达

目的:建立泛素蛋白酶系统(UPS)在正常和8周糖尿病大鼠视网膜的表达图谱,探讨其在糖尿病视网膜病变(DR)发生发展中可能的分子机制。方法:在限制片段差异显示PCR(RFDD-PCR)技术建立正常和8周糖尿病大鼠视网膜基因表达谱的基础上,对差异片段进行生物信息学分析,筛选UPS DR相关基因,并以免疫组织化学、半定量RT-PCR技术进行验证。结果:RFDD-PCR结果显示,泛素蛋白酶系统DR相关基因UBS3A、PSMD8和PSMD11在糖尿病组表达上调。RT-PCR结果显示,糖尿病组UBS3A表达比正常组明显增高,PSMD8和PSMD11则仅在糖尿病组中表达。免疫组织化学结果显示,正常组UBE3A阳性免疫反应物见于内丛状层,外丛状层和锥、杆体细胞层,PSMD8和PSMD11未见阳性细胞;糖尿病组UBE3A、PSMD8和PSMD11阳性细胞明显增多,见于节细胞层、内核层和外核层。结论:UPS与DR发生发展有关。     

Chondroitin sulfate proteoglycans and microglia prevent migration and integration of grafted Müller stem cells into degenerating retina

At present, there are severe limitations to the successful migration and integration of stem cells transplanted into the degenerated retina to restore visual function. This study investigated the potential role of chondroitin sulfate proteoglycans (CSPGs) and microglia in the migration of human Müller glia with neural stem cell characteristics following subretinal injection into the Lister hooded (LH) and Royal College of Surgeons (RCS) rat retinae. Neonate LH rat retina showed minimal baseline microglial accumulation (CD68-positive cells) that increased significantly 2 weeks after transplantation (p < .001), particularly in the ganglion cell layer (GCL) and inner plexiform layer. In contrast, nontransplanted 5-week-old RCS rat retina showed considerable baseline microglial accumulation in the outer nuclear layer (ONL) and photoreceptor outer segment debris zone (DZ) that further increased (p < .05) throughout the retina 2 weeks after transplantation. Marked deposition of the N-terminal fragment of CSPGs, as well as neurocan and versican, was observed in the DZ of 5-week-old RCS rat retinae, which contrasted with the limited expression of these proteins in the GCL of the adult and neonate LH rat retinae. Staining for CSPGs and CD68 revealed colocalization of these two molecules in cells infiltrating the ONL and DZ of the degenerating RCS rat retina. Enhanced immune suppression with oral prednisolone and intraperitoneal injections of indomethacin caused a reduction in the number of microglia but did not facilitate Müller stem cell migration. However, injection of cells with chondroitinase ABC combined with enhanced immune suppression caused a dramatic increase in the migration of Müller stem cells into all the retinal cell layers. These observations suggest that both microglia and CSPGs constitute a barrier for stem cell migration following transplantation into experimental models of retinal degeneration and that control of matrix deposition and the innate microglial response to neural retina degeneration may need to be addressed when translating cell-based therapies to treat human retinal disease.     

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。     

MK-801 induces c-fos protein in thalamic and neocortical neurons of rat brain

MK-801, a non-competitive N-methyl-D-aspartate (NMDA) receptor antagonist, leads to a dramatic induction of c-fos-like protein in neurons in deep layers of the neocortex, in dorsal and ventral midline thalamic nuclei and in neurons in the central grey of rat brain. This induction of c-fos by MK-801 is dose-and time-dependent occurring within 2 h and dissipating by 24 h after injection (0.5-8.0 mg/kg, i.p.). The mechanism of this paradoxical induction of c-fos by MK-801 is unclear; however, the pattern of induction appears to follow the distribution of the antagonist-preferring NMDA receptor site.     

Mg2+ reduces N-methyl-D-aspartate neurotoxicity in embryonic chick neural retina in vitro

N-Methyl-D-aspartate (NMDA) is a potent neurotoxin that affects cells in the inner layers of the embryonic chick retina exposed in vitro. After exposure of the embryonic day 12 neural retina to 0.5-10.0 mM NMDA for 30 min, 50-80% of the cells in the inner region of the inner nuclear layer and 50-100% of the cells in the ganglion cell layer were hypochromatic. When retinas were incubated with Mg2+ (0.5-10.0 mM) for 15 min and then incubated with Mg2+ and NMDA (0.5 mM) for 30 min, the NMDA effect in the inner layers was dramatically reduced but not abolished. Removal of Mg2+ before NMDA exposure produced retinas as seriously affected as retinas not exposed to Mg2+. Studying the effects of NMDA inhibitors, such as Mg2+, may help elucidate the mechanism of the cytotoxic events that occur in the retina in response to certain excitatory acidic amino acids.     

GABAc受体ρ1亚单位mRNA在大鼠视网膜和移植视网膜的定位

应用原位杂交组织化学技术及放射自显影技术 ,通过同位素 [35 S] -d ATP标记寡聚核苷酸探针 ,研究了 GABAc受体ρ1亚单位 m RNA在大鼠视网膜和移植视网膜的定位。实验结果发现 :ρ1亚单位 m RNA在大鼠视网膜和移植视网膜的分布相似 ,它们都分布在内核层中部和外侧部 (即近外网层侧 ) ,胞体呈椭圆形或卵圆形。正常大鼠视网膜 ρ1亚单位 m RNA杂交阳性细胞最先出现于生后第 12 d;移植视网膜出现于术后第 18d(即相当于正常视网膜生后第 10 d)。杂交阳性细胞的形态和位置提示 :表达 GABAc受体ρ1亚单位 m RNA的细胞可能是视网膜双极细胞。这为揭示视网膜信息调控提供了重要依据     

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。     

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.     

The changing distribution of neurons in the inner nuclear layer from metamorphosis to adult: a morphometric analysis of the anuran retina

Summary The generation and changing distribution of neurons of the inner nuclear layer (INL) in the retina of two anuran species, Bufo marinus and Xenopus laevis, were studied from metamorphosis to adult. Morphometric studies were undertaken at six developmental stages in Bufo and four in Xenopus. The number and thickness of neurons in the INL were established in 29 predetermined retinal locations from serial sections of the eyes cut vertically or horizontally. The total number of neurons in the INL increased from metamorphosis to adult from 826000 ± 185 to 18760000 ± 562 (mean ± SD) in Bufo and from 308000 ± 25 to 877000 ± 31 in Xenopus. Over the same period the surface area of the INL increased about 50-fold from 2 mm² to 96 mm² in Bufo and 5-fold from 2.5 mm² to 13 mm² in Xenopus. In Bufo the difference between the highest cell number (centraltemporal retina) and the lowest cell number in a sample area (dorsal and ventral peripheral retina) was 2.11 at metamorphosis. This ratio increased to 3.41 in the adult. Both the cell number and cell density per sample area in the INL was found to be higher along the nasotemporal meridian of the eye overlying the visual streak of the ganglion cell layer (GCL) of the retina. The retinal distribution of neurons in the INL did not change significantly during postmetamorphic growth in Xenopus. At metamorphosis a 1.71 difference was found between the highest neuron number (retinal ciliary margin) and lowest neuron number (retinal centre) decreasing to 1.51 in the adult. Retinae were labelled with ³H-thymidine in 15 mm Bufos and examined 2, 6, 12 and 18 weeks later. Higher rates of cell addition to the nasal and temporal poles of the INL were found compared with that at the dorsal and ventral poles. The retinal radial growth at the ciliary margin of the dorsal, ventral, nasal and temporal poles between the time of isotope injection and 18 weeks survival was found to be uneven; more radial elongation occurred at the nasal, dorsal and ventral poles and less at the temporal pole. These observations suggest that (a) the neuron distribution of the INL in adult animals approximates that of the GCL and (b) the visual streak-like area of the INL in Bufo develops by a sustained differential cell addition at the temporal and nasal poles of the retina.On leave from the Department of Anatomy, Zhanjiang Medical College, Guangdong,People's Republic of China