花背蟾蜍角膜早期形态发生的超微结构研究

本文用透射电镜对花背蟾蜍角膜早期形态发生(18期至25期即肌肉感应期至鳃盖完全封闭期)过程中超微水平的变化进行了细致的研究。结果表明:从19期至21期(心跳期至胚胎开口期)角膜处于尚无特异分化的预定角膜阶段,其结构与邻近表皮无明显区别;22期至24期末(尾血循环期至右侧鳃盖封闭期)是角膜上皮分化阶段,主要变化是角膜上皮变薄、上皮细胞中的色素颗粒被酶解和经粘液泡排出、上皮下层的形成以及内角膜基质原基细胞层数的增加;25期后进入透明的蝌蚪期角膜,此期上皮下层仍不被间质细胞侵入,内皮和基质是以内角膜基质原基的形式存在。     

胭脂鱼眼早期形态发生研究

采用组织学方法观察了胭脂鱼(Myxocyprinus asiaticus) 眼的发生过程, 结果显示: 胭脂鱼眼的发育经历了眼原基形成期、眼囊形成期、视杯形成期、晶体板形成期、晶体囊形成期、角膜原基形成期、角膜上皮形成期、视网膜细胞增殖期、晶状体成熟期、眼色素形成期以及眼成型期等11个时期。视网膜发育最早, 起始于眼原基的形成, 直至眼成型期分化完成, 形成了厚度不一的8层细胞, 由内向外依次为神经纤维层、神经细胞层、内网层、内核层、外网层、外核层、视杆视锥层和色素上皮层, 且发育历时最长, 约264h。晶状体的发育在视网膜之后, 始于晶体板的形成, 于出膜前期成熟, 发育历时最短, 约74h。角膜发育最晚, 始于角膜原基的形成, 出膜1 d分化为透明的成熟角膜, 发育历时约96h。出膜4 d仔鱼眼色素沉积明显, 视网膜各层分化明显, 晶状体内部完全纤维化, 眼的形态结构基本发育完全。     

小鼠角膜发育期间凝集素受体的分布及变化

用辣根过氧化物酶标记的ConA、WGA和RCA Ⅰ为探针,研究了小鼠发育期间角膜内糖残基的分布和变化。Man残基主要分布在角膜基质和内皮;SA残基主要存在于角膜上皮;Gal残基在角膜上皮和基质中都有分布。Man残基在出生前后的小鼠角膜基质中朝内皮方向呈现递增的梯度。SA和Gal残基随角膜发育最后在成体角膜上皮的外表而密集。胎龄13天是小鼠角膜成纤维细胞合成复合糖的起始时间。     

花背蟾蜍角膜早期形态发生中胶原合成的放射自显影研究

本实验以~3H-脯氨酸为标记物,用放射自显影方法研究了花背蟾蜍眼的早期发育中胶原的合成、分布以及对角膜早期形态发生的作用。结果表明,角膜上皮从开始形成即合成胶原,并在角膜上皮基底面聚积。在角膜开始透明时,角膜上皮、内角膜和晶状体的胶原合成速率都明显增加,提示与角膜分化密切相关。     

花背蟾蜍角膜早期发育中胶原合成,分泌和分布的研究

本文以花背蟾蜍19—25期胚胎为材料,采用半薄切片荧光标记胶原酶术及超薄切片分别在光镜及电镜水平观察了胶原蛋白在角膜早期形态发生中合成及分布并探讨其作用。结果表明:角膜上皮与内角膜细胞均可合成、分泌胶原蛋白。角膜上皮基底细胞与内角膜细胞中细胞器数量与位置随发育过程而发生的变化与角膜上皮及内角膜细胞合成及分泌胶原蛋白有关。     

花背蟾蜍(Bufo raddei Strauch)眼形态发生过程中角膜上皮表面结构的扫描电镜观察

扫描电镜观察表明,花背蟾蜍眼形态发生过程中角膜上皮细胞表面形态结构的变化,大致可分三个阶段。1.从神经管期至肌肉感应期预定角膜上皮表面无明显变化;2.在心跳期和鳃血循环期预定角膜上皮表面出现较多的细胞缢束和其下细胞表面的下陷;3.在以后各期,角膜上皮中纤毛细胞的纤毛逐渐退化消失,在右鳃盖封闭期纤毛细胞全部消失。上述变化与视网膜及其中光感受器的发育分化密切相关,纤毛的退化和消失更精确地反映了这种依赖关系,似可作为角??膜上皮分化的一个形态指标。     

硫酸糖胺聚糖(Sulfated Glycosaminoglycans)在花背蟾蜍眼早期形态发生中的合成

本文用放射自显影追踪注射入胚胎的~(35)S-硫酸盐的方法,研究了花背蟾蜍早期形态发生时眼的各部分组织和细胞外基质中的硫酸糖胺聚糖(Sulfated Glycosaminoglycans简称:硫酸GAG)的合成,并分析了其在眼形态发生中的作用。结果表明:1.在眼早期形态发生时,合成的硫酸GAG主要是硫酸软骨素。2.眼各部分组织中在即将分化时硫酸GAG合成率增高,分化开始后逐渐下降到原基形成时的水平。3.在晶状体被诱导时,在视杯和晶状体相互贴近的组织及两者间的细胞外基质中硫酸GAG的合成率明显增加,提示这是晶状体诱导的重要因素。4.角膜上皮形成时即向角膜上皮下层和细胞外基质分泌硫酸GAG;角膜上皮透明时,合成更多的硫酸角质素。     

花背蟾蜍蝌蚪表皮移植片在角膜诱导中的扫描电镜研究

扫描电镜研究表明,花背蟾蜍蝌蚪在角膜诱导过程中表皮移植片外表面的主要变化是:当移植片细胞中色素消失时,细胞的分泌活动变旺盛,表现在细胞外分泌物增多,这可能与排色素有关。同时移植片细胞表面的微突起和边界嵴日趋细小,移植片透明时它更类似正常角膜。在此期间移植片内表面的主要变化是:细胞外基质不断增加,尤其是胶原纤维的增多和逐渐排列整齐,以及可能由于GAG的合成形成的颗粒状结构的出现和消失,这些都与移植片向角膜上皮分化相关联。由于眼球诱导作用引起的上述变化,都可促进表皮移植片转变为透明的角膜。     

重口裂腹鱼眼早期形态发生研究

采用组织学方法观察了实验室饲养的重口裂腹鱼眼在胚胎和早期仔鱼阶段的发生和形态变化过程。结果显示,重口裂腹鱼眼的发生开始于神经胚时期形成的眼原基,眼原基经过分化和内陷形成双层视杯,最终发育形成视网膜。晶状体和角膜来源于外胚层细胞,晶状体发育主要经历晶体板时期;角膜的发育时间较视网膜和晶状体晚,始于角膜上皮的形成。出膜后3 d仔鱼视网膜发育基本完成,眼色素沉积明显,基本具备眼的功能结构。本研究结果丰富了重口裂腹鱼早期发育的生物学资料,为苗种培育等生产实践提供了理论指导。     

东方蜜蜂背单眼的结构和胚后发育

本研究通过形态解剖和BrdU免疫组织化学方法对东方蜜蜂Apis cerana Fabricius背单眼的胚后发育过程进行了比较研究,结果表明:东方蜜蜂的每一个背单眼都包括角膜晶体、角膜生成细胞、小网膜细胞以及后部的单眼神经。蜜蜂的背单眼起源自头壳上皮;其胚后发育的高峰期集中在蛹发育的前3d;其新细胞主要来源于上皮细胞和圆锥形单眼囊周围细胞的有丝分裂;单眼同脑的联系在P1期前后就已经建立;角膜晶体的形成在P5以后。说明单眼的结构和发育同其功能密切相关。     

Corneal morphogenesis in the Indian garden lizard,Calotes versicolor (agamidae)

The present study traces corneal morphogenesis in a reptile, the lizard Calotes versicolor, from the lens placode stage (stage 24) until hatching (stage 42), and in the adult. The corneal epithelium separates from the lens placode as a double layer of peridermal and basal cells and remains bilayered throughout development and in the adult. Between stages 32– and 33+, the corneal epithelium is apposed to the lens, and limbic mesodermal cells migrate between the basement membrane of the epithelium and the lens capsule to form a monolayered corneal endothelium. Soon thereafter a matrix of amorphous ground substance and fine collagen fibrils, the presumptive stroma, is seen between the epithelium and the endothelium. Just before stage 34 a new set of limbic mesodermal cells, the keratocytes, migrate into the presumptive stroma. Migrating limbic mesodermal cells, both endothelial cells and keratocytes, use the basement membrane of the epithelium as substratum. Keratocytes may form up to six cell layers at stage 37, but in the adult stroma they form only one or two cell layers. The keratocytes sysnthesize collagen, which aggregates as fibrils and fibers organized in lamellae. The lamellae become condensed as dense collagen layers subepithelially or become compactly organized into a feltwork structure in the rest of the stroma. The basement membrane of the endothelium is always thin. Thickness of the entire cornea increases up to stage 38 and decreases thereafter until stage 41. In the adult the cornea is again nearly as thick as at stage 38.     

Ultrastructural localization of sulfated and unsulfated keratan sulfate in normal and macular corneal dystrophy type I

Keratan sulfate (KS) proteoglycans are of importance for the maintenance of corneal transparency as evidenced in the condition macular corneal dystrophy type I (MCD I), a disorder involving the absence of KS sulfation, in which the cornea becomes opaque. In this transmission electron microscope study quantitative immuno- and histochemical methods have been used to examine a normal and MCD I cornea. The monoclonal antibody, 5-D-4, has been used to localize sulfated KS and the lectin Erythrina cristagalli agglutinin (ECA) to localize poly N -acetyllactosamine (unsulfated KS). In normal cornea high levels of sulfated KS were detected in the stroma, Bowman's layer, and Descemet's membrane and low levels in the keratocytes, epithelium and endothelium. Furthermore, in normal cornea, negligible levels of labeling were found for N -acetyllactosamine (unsulfated KS). In the MCD I cornea sulfated KS was not detected anywhere, but a specific distribution of N -acetyllactosamine (unsulfated KS) was evident: deposits found in the stroma, keratocytes, and endothelium labeled heavily as did the disrupted posterior region of Descemet's membrane. However, the actual cytoplasm of cells and the undisrupted regions of stroma revealed low levels of labeling. In conclusion, little or no unsulfated KS is present in normal cornea, but in MCD I cornea the abnormal unsulfated KS was localized in deposits and did not associate with the collagen fibrils of the corneal stroma. This study has also shown that ECA is an effective probe for unsulfated KS.     

Quantitative changes and ultrastructural alterations of the cornea in response to ultraviolet light II. Effects on amphibia; elucidation of desmosomal structure and basement membrane synthesis

The cornea of the urodele amphibian Triturus c. cristatus was studied ultrastructurally in order to provide the basis for a comparison among corneas throughout the vertebrate phylum. The cornea of this salamander consists of relatively thick epithelium and basement membrane and thin Descemet's membrane, unlike the mammalian corneas. The outermost epithelial cells contain Ruthenium Red stainable extracellular filaments and intracellular vesicles which are thought to play a role in the process of lubricating the corneal surface. Occluding junctions have been observed in the apical region of the superficial epithelial cells and are considered as barriers to the intercellular passage of material. A thin substantia propria (stroma) consists of about 40 collagenous highly organized lamellae. The thicknesses of the basement membrane, Descemet's membrane and the epithelium are believed to represent the primitive situation in the process of corneal evolution.     

The fine structure of the boundary tissue of the seminiferous tubule of the camel (Camelus dromedarius)

An ultrastructural study of the boundary tissue of the seminiferous tubule of the camel reveals that it consists of three lamellae; inner fibrous, inner cellular and outer cellular. The inner lamella is subdivided into two homogeneous layers enclosing a third one that contains collagenous fibres and fine filaments. The inner cellular lamella consists of several layers of myoid cells; each layer is separated from the adjacent layer by homogeneous material and varying amounts of collagen. The outer cellular lamella consists predominantly of fibrocytes together with some fibroblasts and scattered collagen.     

The lens organizes the anterior segment: specification of neural crest cell differentiation in the avian eye

During the development of the anterior segment of the eye, neural crest mesenchyme cells migrate between the lens and the corneal epithelium. These cells contribute to the structures lining the anterior chamber: the corneal endothelium and stroma, iris stroma, and trabecular meshwork. In the present study, removal of the lens or replacement of the lens with a cellulose bead led to the formation a disorganized aggregate of mesenchymal cells beneath the corneal epithelium. No recognizable corneal endothelium, corneal stroma, iris stroma, or anterior chamber was found in these eyes. When the lens was replaced immediately after removal, a disorganized mass of mesenchymal cells again formed beneath the corneal epithelium. However, 2 days after surgery, the corneal endothelium and the anterior chamber formed adjacent to the lens. When the lens was removed and replaced such that only a portion of its anterior epithelial cells faced the cornea, mesenchyme cells adjacent to the lens epithelium differentiated into corneal endothelium. Mesenchyme cells adjacent to lens fibers did not form an endothelial layer. The cell adhesion molecule, N-cadherin, is expressed by corneal endothelial cells. When the lens was removed the mesenchyme cells that accumulated beneath the corneal epithelium did not express N-cadherin. Replacement of the lens immediately after removal led to the formation of an endothelial layer that expressed N-cadherin. Implantation of lens epithelia from older embryos showed that the lens epithelium maintained the ability to support the expression of N-cadherin and the formation of the corneal endothelium until E15. This ability was lost by E18. These studies provide evidence that N-cadherin expression and the formation of the corneal endothelium are regulated by signals from the lens. N-cadherin may be important for the mesenchymal-to-epithelial transformation that accompanies the formation of the corneal endothelium.     

Immunoreactivity of the septins SEPT4, SEPT5, and SEPT8 in the human eye.

We aimed to examine the distribution of SEPT4, SEPT5, and SEPT8 in the human eye. For each septin, five to six normal human eyes were examined by immunohistochemical staining of paraffin sections using polyclonal antibodies against SEPT4, SEPT5, and SEPT8 and an avidin biotin complex immunodetection system. SEPT4 immunoreactivity (IR) was detected primarily in the epithelium of cornea, lens, and nonpigmented ciliary epithelium; in the endothelium of cornea and vessels of iris and retina; and in the retinal nerve fiber layer, the outer plexiform layer, the outer segments of the photoreceptor cells, the inner limiting membrane of the optic nerve head, and optic nerve axons. SEPT5-IR was present in corneal endothelial cells, iris tissue, nonpigmented ciliary epithelium, and epithelial cells of the lens. SEPT8-IR almost paralleled that of SEPT4, except for a lower SEPT8-IR of the outer photoreceptor segments and a positive staining of the meningothelial cell nests in the subarachnoidal space of the bulbar segment of the orbital optic nerve. In conclusion, SEPT4, SEPT5, and SEPT8 are expressed in various ocular tissues, each revealing a distinct expression pattern. Both physiological and potential pathophysiological role of septins in the human eye deserve further investigation.     

The ultrastructure of the eye of the mosquitofishGambusia affinis

Summary The ultrastructure of the tissue components of the eye ofGambusia affinis, excluding the sensory cells, is described. The cornea consists of two different sections of collagenous layers of different density. The choroid includes an argentea composed of- and-melanophores, lipopterinophores and a choriocapillaris associated with the rete mirabile of the choroid body. Bruch's membrane, underlying the retinal pigment layer, can develop complex associations with fibroblasts delimiting the choriocapillaris. The outer section (stroma) of the iris includes several cell types that are not found in the inner or vitread section. In adultGambusia the lens capsule is well developed, but in twoweek-oldSarotherodon larvae the lens epithelium is covered only by a glycocalyx.     

小鼠角膜发育期间凝集素受体的分布及变化

Using ConA-HRP and RCAI-HRP as probes, the distribution and changes of glycosides in mouse cornea were studied during pre- and postnatal development. Mannose residues were distributed mainly in stroma and endothelium, sialic acid residues in epithelium and galactose residues in both epithelium and stroma. Mannose residues in stroma showed an increased density toward endothelium before and after birth. Sialic acid and galactose residues were concentrated gradually at the corneal epithelial surface in accompanied with the development of cornea. The embryonic day 13 was the starting day to synthesize glycoconjugates from fibroblasts of mouse cornea.     

Ultrastructural demonstration of proteoglycans in adult rat cornea

Proteoglycans in the adult rat cornea were demonstrated at the electron microscope level using two approaches: (a) staining with cuprolinic blue dye in the presence of 0.3 MgCl2, and (b) immunocytochemical localization of glycosaminoglycans with monoclonal antibodies and protein A-gold complexes. In the stroma two kinds of cuprolinic blue-induced filaments were morphologically differentiated and characterized according to their sensitivity to enzymatic degradations as keratan sulphate-rich and chondroitin-dermatan sulphate-rich proteoglycans respectively. Both types were mostly associated with collagen fibres, occupying the whole stroma except in certain areas whose significance is discussed. By immunocytochemistry, anterior and posterior regions of the stroma were found to be richer in chondroitin sulphate than the middle part, whereas keratan sulphate showed an homogeneous distribution throughout the stroma. Glycosaminoglycans were also detected in corneal basement membranes, epithelium and endothelium. The latter localizations are discussed in the light of what is known at present about the production of glycosaminoglycans by corneal cells.