中华须鳗嗅觉器官形态学观察

利用光学显微镜和扫描电镜观察了10尾不同体长中华须鳗嗅觉器官的结构.结果表明:中华须鳗嗅囊呈楔型;嗅囊膜和嗅囊腹面的透明膜共同围成嗅囊腔;嗅囊长径与眼径的平均比值为2.2倍;每侧嗅囊嗅板数变化范围在30～44之间;嗅板远轴端有一纤毛和嗅孔密集的舌状游离突;嗅板上皮纤毛密集,纤毛细胞表现为3种类型:纤毛感觉细胞、纤毛非感觉细胞和微绒毛感觉细胞;纤毛非感觉细胞和微绒毛细胞也出现在嗅囊壁.嗅板上大量的纤毛表明,中华须鳗嗅囊的水动力机制应属嗅板纤毛搅动型(isosmates).除观察到嗅囊壁表面有两种类型的微嵴外,还首次在嗅板上观察到一种呈荸荠状的杆状细胞.     

暗纹东方鲀侧线系统早期形态和生长发育

通过光镜和扫描电镜对暗纹东方鲀(Takifugu obscurus)的侧线系统进行形态学及组织学的研究。研究结果首次揭示了暗纹东方鲀侧线系统除了主侧线外还包括辅助侧线和辅助神经丘。主侧线分布主要包括眶上线、眶下线、耳后侧线、下颌线、前鳃盖线、上颞线、背侧线、腹侧线。辅助侧线和辅助神经丘分布主要包括口部辅助侧线、眶下辅助侧线、下颌前辅助侧线、下颌后辅助侧线、眶上后辅助侧线、上颞腹辅助神经丘、上颞背辅助神经丘、前鳃盖后辅助神经丘、背部辅助神经丘、尾部辅助神经丘。暗纹东方鲀侧线器官为接受机械刺激的神经丘,数目上千,神经丘分布在体表的凹槽里,且位于高低不同突起顶端。神经丘由套细胞、支持细胞和感觉毛细胞组成。感觉毛细胞呈圆形排列,并且每个细胞的游离面均有一根动纤毛和几十根静纤毛。据本研究对暗纹东方鲀侧线分布特征和神经丘的生长特征等的观察结果,认为尽管暗纹东方鲀侧线系统没有如其他真骨鱼类的管道系统,但是依然具有两套不同生理机能的机械感受系统,符合"七管模式"的主侧线神经丘与管道神经丘同源,而辅助侧线和辅助神经丘才是真正的表面神经丘。     

东亚飞蝗Locusta migratoria manilensis（Mey．）膝下器中感觉细胞的超微结构

东亚飞蝗滕下器由具橛感器组成,每一具橛感器主要由三类细胞组成,即：感觉细胞、感橛细胞和冠细胞。感觉细胞位于最近端．细胞核圆且大,细胞质内含有丰富的线粒体、高尔基体、多泡小体等细胞器。感觉细胞向近端发出轴突进入中枢神经系统,向远端发出树突。树突内古有大量的线粒体、纵行微管,树突内最复杂的结构当属纤毛根,从近端到远端依次由远端基体、近端基体、主纤毛根和纤毛小报组成。树突顶端,由远端基体发出一条感觉纤毛,纤毛具有典型的“9 0”结构。主纤毛根和纤毛小根具有明暗相间横纹结构,两横纹间的间隔距离约为65nm。感觉纤毛穿过由感橛细胞形成的感橛空隙,末端进入一高电于密度的顶端细胞外结构——帽。感橛细胞内最明显的特征为具有感橛,感橛细胞围绕着远端树突和感觉纤毛部分,冠细胞紧密地包围着感橛细胞和帽。东亚飞蝗膝下器中同时古有一或两个感觉细胞的具橛感器,这在以往研究报道中是较为少见的。本研究的主要目的在于为以后对此器官的生理功能研究提供形态学的基础材料。     

可口革囊星虫肾管纤毛的分布及结构特征

为了解可口革囊星虫(Phascolosoma esculenta)肾管纤毛的结构特点及其功能,采用显微及亚显微技术观察研究了可口革囊星虫肾管纤毛的分布位置及形态结构特征。结果表明,肾管外膜多纤毛细胞表面簇生纤毛、内部柱状上皮细胞与立方上皮细胞游离面着生分散的纤毛,肾口内面也着生纤毛。纤毛结构由纤毛干、过渡区、基体及其纤毛小根组成;纤毛干由"9+2"结构的轴丝外被纤毛膜构成;纤毛干与基体之间为过渡区,中央微管终止于此,外周双联微管通过过渡区和基体的外周轴丝相连;基体呈圆筒状,为"9+0"结构;纤毛小根分长根和短根,均为基体发出的由微细原纤维组成的圆锥形结构,具间隔70 nm的明显横纹。肾管纤毛可能在促进体腔液流动、提高肾管对体腔液的过滤作用以及引导成熟精卵进入肾管等方面发挥作用。     

版纳鱼螈侧线系统的结构

版纳鱼螈(Ichthyophis bannanica)是我国无足目的仅有代表,应用光镜和扫描电镜对版纳鱼螈的侧线系统进行形态学和组织学观察的研究表明:版纳鱼螈幼体表皮中的侧线器官有接受机械刺激的神经丘和电接受壶腹器官两种,神经丘包括表面神经丘和陷神经丘。侧线分布主要包括:头部的鼻侧线、眶上线、眶下线、眶后线、口侧线、下颌线、咽侧线、鳃孔上线和身体上的背侧线。侧线器官的分布密度、大小和凹陷深度明显与周围表皮的厚度和不同部位有关。幼体的侧线器官退化与鳃孔的退化同步,亚成体以后不保留侧线系统。版纳鱼螈的侧线分布和器官结构与其它无足类的大致相似,仅在眶上线和眶下线的器官分布上存在微小的差别     

纤毛、纤毛发生与Wnt/PCP信号通路

纤毛是以微管为核心组分、突出于细胞表面且高度保守的细胞器,具有运动、摄食、感知并传递外界信号等功能。纤毛发生是纤毛在细胞膜表面定位并装配的过程。多年来,对纤毛发生过程及其调控机制的探索始终是亚细胞结构与功能研究的热点之一。Wnt/PCP信号通路是参与胚胎及器官发育的主要信号转导途径之一。近年来大量研究显示,Wnt/PCP信号通路和纤毛发生密切相关。纤毛结构与功能的异常可造成Wnt/PCP信号通路异常,导致纤毛相关疾病的发生;同时,Wnt/PCP信号通路又决定着纤毛的形态和极性。因此,深入研究纤毛与Wnt/PCP信号通路的关系将有助于从细胞与分子生物学水平揭示纤毛发生的调控机制。     

DNA与个体发育调控(2)

生物结构的形成需要各种细胞按照类型分别聚集,这主要是通过细胞表面的钙黏蛋白实现的。形成片、管、腔等结构需要细胞具有极性;上皮表面上的的结构如纤毛、羽毛、鳞片、毛发具有方向性,也需要有关细胞具有极性。细胞的极性是由细胞内和细胞表面的一些蛋白质聚合物彼此拮抗并不对称分布而形成的。细胞之间通过Notch蛋白及其配体之间的相互作用导致彼此相邻的细胞向不同的分化方向发展。这些"成型分子"在胚胎发育过程中都发挥重要的作用。     

杂色鲍头触角的显微与亚显微结构

本文采用光镜和电镜方法,研究了杂色鲍(Haliotisdiversicolor)头触角的显微和亚显微结构。结果表明,杂色鲍头触角的表皮布满乳头状突起,突起表面布满微绒毛,顶端具纤毛。头触角作为重要的感觉器官之一,具触觉兼嗅觉功能,其上皮为特殊的感觉上皮,其组成细胞主要包括三种类型:支持细胞、感觉细胞、腺细胞。头触角表皮之下的成分为平滑肌纤维和疏松结缔组织,疏松结缔组织里含胶原纤维、成纤维细胞、肥大细胞、微孔细胞、变形细胞等成分。     

鲫鱼松果体的显微和超微结构研究

本文作者发现鲫鱼的松果体与一般硬骨鱼不同,它除由背囊和背囊内褶中松果管所组成的松果体外,还有退化的旁突体和副松果体.背囊是单层柱状纤毛上皮,其腔与第3脑室相通,松果管由光感觉细胞、支持细胞、节细胞、丰富的血管和无髓神经纤维构成.松果体既是光感受器又有内分泌的功能.       

鲇鱼须部味蕾细胞的超微结构研究

味蕾作为一种感觉器官早已为人们所重视,并且许多学者对它的形态与功能进行了广泛的研究,积累了丰富的资料。味蕾Dark细胞(以下简称D细胞)和Light细胞(以下简称L细胞)是味蕾的两种主要细胞类型,它们的命名是基于甲醛固定后在光学显微镜下的描述(Heidenhain,1914)。在机能上,D细胞长期被推测是感觉细胞;近年来,不少报道认为D细胞是分泌细胞,而原来被认为是支持细胞的L细胞则逐渐被认为是感觉细胞     

Ultrastructure of the skin mechanoreceptors of the Chinese giant salamander, Andrias davidianus

The ultrastructure of two kinds of mechanoreceptive organs, pit organs and neuromasts, in the skin of adult giant salamanders (Andrias davidianus) was studied by transmission electron microscopy. Neuromasts and pit organs differ in their types of synapses, the spatial distribution of kinocilia on sensory cells, and in the degree to which sensory cells are separated by processes of the supporting cells; the two organs probably serve complementary functions. The neuromasts in A. davidianus differ from those of other salamanders in the orientation of kinocilia, in the extent of intrusion of supporting cells into the sensory layer, in the degree of thickening of the synaptic membranes, in the distribution of synaptic spheres, and by the absence of a cupula.     

中国大鲵侧线器官的研究

本文以光镜和扫描是镜手段研究了中国大鲵幼体，亚成体及成体头部及躯干部表皮中的侧线器官，即电接受壶腹器官，机械接受的表面神经丘和陷器官的分布，形态和发展变化。壶腹器管仅存于幼体头部，变态结束后消失，后两种终生存在，但前者按一定路线和方向排列，后者仅存于头部，陷在表皮中，文章探讨了壶腹器官的原始性，其消失与生活习性以及由水登陆进化的关系；对三种器官的形态及其它有尾类的侧线器官进行了比较。     

The fine structure of the lateral-line organs of larval Ichthyophis (Amphibia: Gymnophiona)

Light and electron microscopic observations of the lateral-line organs of larval Ichthyophis kohtaoensis confirmed earlier reports of the occurrence of two different types of lateral-line organs. One type, the ampullary organ, possesses 15–26 egg-shaped sensory cells. Each sensory cell extends a single kinocilium surrounded by a few microvilli into the ampullary lumen. This is in contrast to the ampullary organs of urodele amphibians that contain only microvilli. The second type of organ, the ordinary neuromast, has 15–24 pear-shaped sensory cells arranged in two to three rows. Each sensory cell shows a kinocilium that is asymmetrically placed with respect to both a basal plate and approximately 60 stereovilli. The sensory cells of ampullary organs are always separated by supporting cells; those of neuromasts are occasionally in contact with one another. Numerous (neuromasts) or few (ampullary organs) mantle cells separate the organs from the epidermal cells. Only afferent synapses are found in the ampullary organs whereas vesicle-filled fibers together with afferent nerve terminals are found in neuromasts. Both organs contain similarly sized presynaptic spheres adjacent to the afferent fibers. It is suggested that the neuromasts have a mechanoreceptive function, whereas the ampullary organs have an electroreceptive one.     

中国大鲵消化系统13种器官的蛋白水解酶种类和活性分析

蛋白水解对生命活动是必不可少的(Vassali et al., 1994),蛋白质的酶解修饰(Xu et al.,1999)、细胞的迁移、组织再生与修复、消化系统对食物中蛋白质的消化等均与蛋白水解酶有关(Baimbridge et al.,1992),许多病理过程也与蛋白水解酶功能失调有关(Teichert et al., 1989; Monard, 1988).因此开展大鲵消化系统各器官的蛋白水解酶种类和性质的研究,对了解大鲵消化系统各器官的功能、演化及大鲵的营养需求、食性、消化生理等是必要的.本文对大鲵消化系统各器官的蛋白水解酶特征进行了初步分析,现将结果报道如下.     

Some evidence for the ampullary organs in the European cave salamander Proteus anguinus (Urodela,Amphibia)

Summary The multicellular epithelial organs in Proteus anguinus, which Bugnion (1873) assumed to be developing neuromasts, have been analyzed by lightand electron-microscopy. Their fundamental structure consists of single ampullae with sensory and accessory cells with apical parts that extend into the pit of the ampulla, and of a short jelly-filled canal connecting the ampulla pit with the surface of the skin. The organs are located intra-epithelially and are supported by a tiny dermal papilla. The cell elements of sensory epithelium are apically linked together by tight junctions. The free apical surface of the sensory cell bears several hundred densely packed stereocilia-like microvilli whereas the basal surface displays afferent neurosensory junctions with a pronounced round synaptic body. The compact uniform organization of the apical microvillous part shows a hexagonal pattern. A basal body was found in some sensory cells whereas a kinocilium was observed only in a single cell. The accessory cells have their free surface differentiated in a sparsely distributed and frequently-forked microvilli. The canal wall is built of two or three layers of tightly coalescent flat cells bordering on the lumen with branching microvilli. The ultrastructure of the content of the ampulla pit is presented.In the discussion stress is laid on the peculiarities of the natural history of Proteus anguinus that support the view that the morphologically-identified ampullary organs are electroreceptive. The structural characteristics of ampullary receptor cells are dealt with from the viewpoint of functional morphology and in the light of evolutionary hypotheses of ampullary organs.     

Ultrastructure of the nuchal organ in the interstitial polychaete Stygocapitella subterranea (Parergodrilidae)

The nuchal organs of Stygocapitella subterranea are paired narrow pits. They are lined by unciliated cells at the opening and by ciliated cells at the basal parts. The primary sensory cells (6–8) are arranged in a single patch at the bottom of the nuchal pit. The nuclei of the sensory cells are located in the posterior portion of the brain. Their dendrites form the nuchal nerve which is sheathed by the ciliated cells. Each sensory cell bears up to 4 modified sensory cilia and several microvilli extending into the olfactory chamber. The sensory cilia show various patterns of axonemal organization and have no rootlets. The olfactory chamber is covered by a cuticular matrix. Another primary sensory cell lies at the opening of the nuchal pit. It bears cilia which penetrate the cuticle but are enveloped by the epicuticle. Retractor muscles insert caudally on the organ. The nuchal organ of S. subterranea shows similarities to those of opheliids but exhibits several features not to be found in other nuchal organs.     

An NIR emitting styryl dye with large Stokes shift to enable co-staining study on zebrafish neuromast hair cells

Hearing loss is a significant public health problem, and the “loss of sensory hair cells” is one of two leading causes in humans. Advanced imaging reagents are desirable for understanding the role of the surrounding support cells in the loss or regeneration of the hair cells. A styryl dye was found to exhibit NIR emission (λ_em ≈ 684 nm) with a very large Stokes shift (Δν ≈ 9190 cm⁻¹), due to the incorporation of excited state intramolecular proton transfer (ESIPT) mechanism. When used to stain live zebrafish embryos, the probe was found to exhibit good selectivity in targeting neuromasts, which are sensory organs on the surface of the fish’s body. The finding was verified by direct comparison with the known neuromast-labeling reagent, 4-Di-2-ASP. In contrast to the existing styryl dyes that label neuromast hair cells, the new probe labeled both neuromast hair cells and the surrounding support cells, while giving discernable signals. The study thus illustrated a useful tool to aid the developmental study of two closely related cell types on the mechanosensory sensory organ of zebrafish, which is a powerful animal model for hearing loss research.     

The lateral line system in larvalIchthyophis (Amphibia: Gymnophiona)

Summary The lateral line systems of larval caecilians of the genusIchthyophis possess two types of elements, free neuromasts and ampullary organs. Free mechanoreceptive neuromasts are typical of those found in other vertebrates, and are arranged in series roughly homologous to neuromast groups in many other fishes and amphibians. In contrast to other amphibians,Ichthyophis larvae possess only one paired, dorsal body series of neuromasts. Regional specialization of neuromasts is evident inIchthyophis. Premaxillary and anterior head neuromasts are the largest in size and total cell number. Overall, size and total cell numbers are correlated with depth of epidermis. Neuromasts on the anterior sides of the head occur in slight grooves and have apical tips situated farther below the level of the epidermis and with greater apical indentation. These features probably provide increased protection against abrasion. Apparently abnormal neuromasts are frequently found among the neuromast series. Such neuromasts contain fewer cells that lack normal apical extension, producing a sunken effect similar to that of the ampullary organ elements. The ampullary organs ofIchthyophis are morphologically similar to those found in various freshwater fishes and known to function as electroreceptors. These organs are not observed in the lateral line systems of members of other amphibian orders (Urodela and Anura), and we suggest that they function as electroreceptors. The sunken neuromasts of theIchthyophis lateral line system may parallel the possible evolutionary development of pit organs from normal neuromasts.     

Developmental origin of shark electrosensory organs

Vertebrates have evolved electrosensory receptors that detect electrical stimuli on the surface of the skin and transmit them somatotopically to the brain. In chondrichthyans, the electrosensory system is composed of a cephalic network of ampullary organs, known as the ampullae of Lorenzini, that can detect extremely weak electric fields during hunting and navigation. Each ampullary organ consists of a gel-filled epidermal pit containing sensory hair cells, and synaptic connections with primary afferent neurons at the base of the pit that facilitate detection of voltage gradients over large regions of the body. The developmental origin of electroreceptors and the mechanisms that determine their spatial arrangement in the vertebrate head are not well understood. We have analyzed electroreceptor development in the lesser spotted catshark (Scyliorhinus canicula) and show that Sox8 and HNK1, two markers of the neural crest lineage, selectively mark sensory cells in ampullary organs. This represents the first evidence that the neural crest gives rise to electrosensory cells. We also show that pathfinding by cephalic mechanosensory and electrosensory axons follows the expression pattern of EphA4, a well-known guidance cue for axons and neural crest cells in osteichthyans. Expression of EphrinB2, which encodes a ligand for EphA4, marks the positions at which ampullary placodes are initiated in the epidermis, and EphA4 is expressed in surrounding mesenchyme. These results suggest that Eph-Ephrin signaling may establish an early molecular map for neural crest migration, axon guidance and placodal morphogenesis during development of the shark electrosensory system.