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     

西伯利亚鲟仔鱼侧线系统的发育

鲟鱼属软骨硬鳞鱼,在电感受器的进化中占据着极为重要的地位。该文以光镜和扫描电镜手段研究了西伯利亚鲟侧线系统早期发育,包括侧线基板发育及感觉嵴的形成、侧线感受器的发育和侧线管道的形成。1日龄,听囊前后外胚层增厚区域出现6对侧线基板;除后侧线基板细胞向躯干侧面迁移外,其他侧线基板均形成感觉嵴结构;每一侧线基板中均有神经丘原基形成。7日龄,壶腹器官在吻部腹面两侧出现,壶腹器官的发育比神经丘晚一周左右。9日龄,神经丘下的表皮略有凹陷,侧线管道开始形成。29日龄,在吻部腹面两侧可见少数个别的壶腹器官表皮细胞覆盖壶腹器官中央区域留下3～4个小的开口;壶腹管内可见大量的微绒毛存在,在其他鲟形目鱼类、软骨鱼类中也存在类似的结构。57日龄,躯干侧线管道已完全埋于侧骨板中;壶腹器官主要分布在吻部腹面,3～4个聚集在一起,呈"梅花状",分布紧密,并且该部分皮肤表面凹陷,形成花朵状凹穴;侧线系统发育完善。     

中国大鲵机械感受器的超微结构

首次以透射电镜研究了大鲵成体（实验材料共两条）皮肤侧线器官中机械受器即表面神经丘和陷器官的超微结构,并在这两种感受器官之间进行了比较。它们都由三种细胞组成：周围的套细胞,底部的支持细胞以及中央的感觉细胞;且感觉细胞的游离面均有一根动纤毛和几十根静纤毛。但这两种器官在大小、各种细胞的数量、形状和排列上下不同,尤其是表面神经丘感觉细胞游离面纤毛具有双向极性,而陷器官体现为多向极性;表面神经丘的突触球集中分布于一个特殊的感觉细胞,而陷器官的每个感觉细胞基部都有一个突触球。     

版纳鱼螈幼体和成体皮肤的结构

采用光镜和扫描电镜,对我国特有的珍稀濒危两栖动物版纳鱼螈Ichthyophis bannanicus幼体和成体的皮肤进行形态学和组织学观察.版纳鱼螈幼体和成体的皮肤均可分为表皮、真皮疏松层和真皮致密层;皮肤中含有粘液腺和颗粒腺;在不同发育阶段或同一个体的不同部位,其皮肤的各种组成成分在结构和厚度上存在着差异:成体和幼体都是头部的表皮最厚,尾部的最薄;幼体表皮各层细胞分化不明显,几无角化现象,成体表皮的各层细胞分化明显,表层细胞明显角化;成体躯干部皮肤最厚,头部最薄,幼体则是头部皮肤最厚,尾部最薄;幼体和成体的头部皮肤都分布有大量的粘液腺,颗粒腺分布较少;幼体的躯干部皮肤则主要分布着大量颗粒腺,尾部只有颗粒腺,未见粘液腺;成体躯干部和尾部皮肤均分布有大量的颗粒腺和粘液腺.     

四刺泡角跳（Ceratophysella duplicispinosa）个体发育的初步研究

描述了北方菜园优势跳虫四刺泡角跳（Ceratophysella duplicispinosa）的胚胎发育及胚后发育过程。结果表明：①四刺泡角跳为聚产卵,每窝卵数22-53粒,卵粒D=220μm。②其胚胎发育历时约8．3d（200h）,行完全均等卵裂,以内陷方式形成二胚层;③组织器官分化早期背面中部出现凹陷,成为头部与胸腹部最早的界限,同时在腹面出现附肢原基;④无体节幼虫期的触角、口器、足、腹管、弹器及腹部尾叶等器官都以附肢原基的形式出现,至孵化前期显现出各器官形态：出壳前3d开始出现一对红色眼斑。⑤胚后发育（自孵化出壳至首次产卵）历时29d,体色先后为白色（初孵化幼体）、棕红至灰色（亚成体）、紫黑色（成体）。     

大鲵呼吸系统的解剖

大鲵是我国珍贵的两栖类动物。呼吸系统的解剖学观察,为研究脊椎动物的进化提供依据。大鲵呼吸系统的解剖,幼体以外鳃呼吸,成体以肺呼吸为主,在个体发育过程中,呼吸系统相应地出现一系列器官变化。另外,大鲵的皮肤是呼吸的辅助器官。     

中国大鲵的食性研究

１９８５－１９８８年，在陕西秦岭，大巴山中，先后１０个月共采集中国大鲵标本７１尾，其中幼林４０尾，成体３１尾。经过剖胃，观察胃容物并称重，分析中国大鲵食物的种类和数量。解剖中空胃４０尾，实胃３１尾，中国大鲵是肉食性捕食动物，幼体以螃蟹，昆虫等小型水生动物为食；成体以螃蟹，鱼，青蛙和水麝鼯等水生动物为食。     

泽陆蛙(Fejervarya limnocharis)两性异形的个体发育和雌体繁殖

2010年3月下旬-7月上旬于浙江富阳市农田采集680只泽陆蛙(Fejervarya limnocharis),研究了泽陆蛙成体和幼体的个体大小和局部形态特征的两性异形;通过解剖雌体获得窝卵数、测量抱对个体获得形态数据,研究了雌体大小与生育力关系以及抱对两性个体体形大小的相关性.结果表明:捕获个体中,雌性和雄性成体的最小体长分别为33mm和30 mm;雄性成体个体数显著超过雌性成体,两性幼体个体数无显著差异;两性成体头部大小、四肢长随体长呈同速增长,眼径和体重随体长呈异速增长,两性幼体所有被检形态特征均随体长呈同速增长;雌性成体平均体长显著大干雄性成体,去除体长差异的影响后发现,除眼径无显著的两性差异外,其余被检形态特征均为雌性大于雄性;幼体除雌性体重大于雄性外,其余被检形态特征均无两性差异;窝卵数与雌体大小(体长和体重)呈显著的正相关;两性抱对个体的体长无显著相关性;泽陆蛙雄性成体体形小于雌性成体的个体大小两性异形模式可能决定于驱使雄性向较大体形发展的进化驱动力相对较弱,雌性增大体形可增加繁殖输出,故向较大体形发展的进化驱动力相对较强;除体重外,其余被检形态特征的两性异形均形成于性成熟之后.     

大鲵生殖系统发育研究

大鲵是我国特有的大型有尾两栖类,是国家二类保护动物,在医药、食用和观赏等方面都有一定的价值。笔者通过41尾幼体,29尾成体的浸液标本的解剖,观察了大鲵生殖系统的发育变化,大鲵的幼体外鳃萎缩后,性分化基本分明。体长在260毫米以上的个体,性腺发育基本成熟,参与繁殖。     

蓝尾石龙子的头部两性异形和食性

通过测量头、体大小和胃检研究浙江泰顺产蓝尾石龙子 (Eumeceselegans)个体发育过程中两性异形和食性的变化。蓝尾石龙子成体个体大小和头部大小的两性差异显著 ,雄性大于雌性。不同发育阶段雌性头长与SVL的线性回归斜率无显著差异 ,头宽与SVL线性回归斜率的差异显著 ,成体和SVL <5 0mm幼体头宽随SVL的增长速率显著小于SVL为 5 0 - 6 9mm的幼体。雄性头部相对于SVL呈加速式异速生长。两性比较发现 :雌雄幼体头长和头宽随SVL的增长速率无显著差异 ,SVL <5 0mm幼体特定SVL的头长和头宽无显著的两性差异 ,但SVL为 5 0 - 6 9mm的雄性幼体头长和头宽大于SVL相同的雌性幼体 ;雄性成体头长和头宽随SVL的增长速率显著大于雌性。SVL <5 0mm的雌性幼体头部相对小于SVL为 5 0 - 6 9mm的同性幼体 ,性成熟雌体头部相对小于SVL为 5 0 - 6 9mm的同性幼体。雌性幼体、雄性幼体、雌性成体和雄性成体食物生态位宽度分别为 12 3、 12 5、 4 8和 14 4。雌雄幼体食物生态位重叠度最高 ,雌雄成体食物生态位重叠度次之 ,成体与幼体食物生态位重叠度较小。成体摄入食饵的大小 (用胃内完整食物长度的平均值表示 )和变化范围大于幼体。两性成、幼体摄入的食饵大小差异显著。两性个体摄入的食饵大小均与其SVL呈正相关 ,表明较大     

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.     

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.     

Pit organs in axolotls: a second class of lateral line neuromasts

The lateral line system of axolotls (Ambystoma mexicanum) consists of mechanoreceptive neuromasts and electroreceptive ampullary organs. All neuromasts in salamanders are located superficially and are organized into lines that are homologous to canal neuromasts in fishes. Ampullary organs are confined to the head and generally are located adjacent to the lines of superficial neuromasts. Axolotls, however, also possess a third class of receptors; these form restricted patches on the head and are possibly homologous to the superficial pit organs in fishes. In order to test this hypothesis the morphology of the suspected pit organs was examined with scanning electron microscopy, and a number of their physiological properties were determined. Pit organs are approximately half the size of neuromasts and have fewer hair cells, although these hair cells do possess kinocilia and stereocilia like those of neuromasts. Pit organs also possess cupulae and exhibit a pattern of innervation identical to that of neuromasts. Pit organs and neuromasts also exhibit similar rates of spontaneous activity, are excited by weak water currents but not weak electric stimuli, and are not inhibited by magnesium ions. Pit organs appear to have slightly lower rates of spontaneous discharge than neuromasts, however, and have slightly lower displacement thresholds to low frequency wave stimuli. These data support the contention that the pit organs of axolotls constitute a second class of neuromasts homologous to the pit organs of fishes.     

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.     

The evolution of the amphibian lateral line system and its bearing on amphibian phylogeny

In modern amphibians that are aquatic the lateral line system is organized, by order, as follows: caecilians have electroreceptive ampullary organs and single rows of mechanoreceptive neuromast organs; generalized anurans have single rows of neuromasts that divide in a transverse plane to form secondary neuromasts or stitches, they do not have ampullary organs; generalized urodeles have ampullary organs, transverse stitches, and double or triple rows of neuromasts. Fossil evidence indicates that early amphibians had both ampullary organs and single rows of neuromasts embedded in bone. With time, receptors became epidermal in all three orders. Modern caecilians have retained the primitive receptor arrangement. I propose that the common ancestor of anurans and urodeles had transverse stitches, and that this character allies these two groups. Subsequent to the anuranurodele split, anurans lost their ampullary organs, perhaps concomitant with developing specializations for herbivory. Urodeles developed orthogonal neuromast couplets und triplets. In modern anurans und urodeles, transverse stitches are correlated with pond dwelling, while ampullary organs are correlated with carnivory, suggesting that the anuran-urodele ancestor(s) was a (were) pond-dwelling carnivore(s).     

The comparative morphology of pit organs in elasmobranchs

The pit organs of elasmobranchs (sharks, skates and rays) are free neuromasts of the mechanosensory lateral line system. Pit organs, however, appear to have some structural differences from the free neuromasts of bony fishes and amphibians. In this study, the morphology of pit organs was investigated by scanning electron microscopy in six shark and three ray species. In each species, pit organs contained typical lateral line hair cells with apical stereovilli of different lengths arranged in an “organ‐pipe” configuration. Supporting cells also bore numerous apical microvilli taller than those observed in other vertebrate lateral line organs. Pit organs were either covered by overlapping denticles, located in open grooves bordered by denticles, or in grooves without associated denticles. The possible functional implications of these morphological features, including modification of water flow and sensory filtering properties, are discussed. J. Morphol. 2009. © 2009 Wiley‐Liss, Inc.     

Fine structure and histochemistry of the ampullary organ of the urodele amphibian Pleurodeles

A morphological study by light and electron microscopy on the lateral line system of the urodele amphibian Pleurodeles waltii demonstrates the presence of sensory organs other than neuromasts in the head. From their morphology, they have been called ampullary organs. The ampullary organs occur in the bottom of a groove and consist of three different types of cells: sensory, supporting and mantle cells. Histochemical analysis indicates that the last two are secretory cells, probably involved in the production of the material filling the ampulla and the groove.