松果体对“生物钟”的调节

松果体对“生物钟”的调节刘开乾（江西省永新县涅田中学３４３４０６）松果体是由原始脊椎动物的松果眼发展而来的一种内分泌腺体。腺体外有结缔组织被膜包着,被膜还伸人腺实质中,把腺实质分隔成不规则的小叶。腺实质里由松果体细胞和神经胶质细胞构成,神经胶质细胞围...     

脊椎动物松果器官的形态结构比较和演化初探

对脊椎动物６个纲中日本七鳃鳗、鲫鱼、黑斑蛙、丽斑麻蜥、家鸽和高原鼠兔等几种动物松果器官的形态结构进行了观察和比较,并对其演化作了初步探讨。脊椎动物的松果器官分为二大类,一类为变温动物的松果器官,由副松果体和松果体构成,其中副松果体是一个典型的光感受器,松果体亦主要具有感光的结构。另一类为恒温动物的松果器官,仅包含松果体,无副松果体,其结构主要具有内分泌腺的特征。在系统演化中,后一类松果器官可能是由前一类演变来的。从演化揭示：最早脊椎动物的松果眼是２个。哺乳动物的松果腺是由一种光感受器演变来的。     

高原鼠兔松果体超微结构的研究

本文采用光镜和透射电镜对高原鼠兔松果体的形态结构进行了观察,并对其结构与功能的关系怍了初步探讨：1． 高原鼠兔的松果体与其他哺乳动物的基本相似, 包括深、浅两部分, 两部分的细胞构筑及其形态基本一致,主要由松果体细胞、胶质细胞、神经细胞、微细血管和神经纤维组成。松果体细胞有明、暗两种,两种细胞胞质内均有丰富的线粒体、高尔基复合体、粗面和滑面内质网,以及游离核糖体,还可见极少数微管和脂滴等。2． 松果体细胞内囊泡、微管和突触带的数量与细胞的分泌功能密切相关。3． 松果体分泌物主要通过二种方式释放：(1)通过扩散和胞吐作用,将分泌物释放到细胞外或血管周隙;(2)分泌物直接进入第三脑室。     

松果体和癫痫

松果体的生理功能近年来引起了人们的重视,它与神经内分泌的关系,尤其与生殖内分泌的关系,早已引起了广泛的重视。近年来发现,松果体与中枢神经系统的某些功能也有密切关系。本文重点讨论松果的主要生物活性物质——麦拉托宁的生物合成、转化以及它和原发性癫痫的关系。一、松果体内吲哚类生物活性物质的分离、生物合成和转化松果体的多种生理功能,主要是通过其多种生物活性物质实现的,这些物质包括去甲肾上腺素(NE)、组织胺、5-羟色胺(5-HT)和其它吲哚类。后者是松果体的主要生物活性物质,松果体的许多生理功能,大多是通过这些吲哚类实现的。     

松果体及其褪黑素对大鼠胸腺细胞凋亡的影响

目的探讨松果体及其褪黑素对胸腺细胞凋亡的影响以及Caspase-3的表达。方法选用清洁级SD大鼠,分为正常对照组、假手术对照组、松果体摘除组、松果体摘除 褪黑素腹腔注射7.5mg/kg/d组和松果体摘除 褪黑素腹腔注射15mg/kg/d组。术后4、8周取材。运用TUNEL法检测胸腺细胞的凋亡程度,用ABC法染胸腺Caspase-3阳性细胞,计算机图像分析仪测量阳性细胞面积及其染色强度。以RT-PCR法检测褪黑素干预原代培养胸腺细胞Caspase-3的表达。结果松果体摘除后8周时胸腺细胞凋亡显著增加,补充褪黑素则能明显减少胸腺细胞的凋亡。Caspase-3阳性细胞主要见于胸腺皮质,松果体摘除后胸腺皮质Caspase-3阳性细胞面积增加明显,补充褪黑素则使其下降。褪黑素能上调培养胸腺细胞Caspase-3的表达水平。结论松果体能调控大鼠胸腺细胞的凋亡,松果体摘除促进胸腺细胞的凋亡,补充褪黑素能缓解相关影响。     

松果体

松果体张世彪（天津市静海县教师进修学校３０１６００）松果体是由原始脊椎动物的松果眼发展而来的一种内分泌腺体,在高等脊椎动物中,为一卵形小体,位于间脑背面。人的松果体位于四叠体上丘之间的凹陷内,有一个柄与第三脑室的后顶相连,其大小只有０．１９ｃｍ’,重...     

羊松果体细胞原代培养及其生物学特性的研究

体外培养山羊及绵羊的松果体细胞,观察其增殖情况和功能状态的变化.结果显示:山羊、绵羊的松果体细胞体外形态及生长情况相似.细胞多呈圆形或多角形,细胞体积有增大趋势.采用MTT法检测细胞生长状态,发现细胞有明显的增殖现象,大约于11d达到高峰.用免疫组织化学对培养细胞进行染色,发现5-HT阳性细胞数量随细胞的增殖而增加.表明山羊和绵羊松果体细胞在体外均增殖旺盛,并能保持体内的分泌功能.     

青蛙光敏感松果体神经节细胞自发放电的昼夜节律变化

为了研究青蛙松果体的昼夜节律,本实验采用细胞外连续记录,研究了松果体内对光产生抑制反应的光敏神经节细胞放电的昼夜节律变化.结果表明(1)所有表现自发放电的细胞,其放电频率介于1-6Hz之间,脉冲发放特征有规则、不规则(或波动)和阵发等方式;(2)无论在持续黑暗(DD)、持续光照(LL)或在模拟自然光照周期(L-D-L)任何一种条件下所进行的昼夜连续记录都显示:有些细胞在白天放电频率低,在夜间放电增强;而另一些细胞则在整个记录过程中,其脉冲频率基本上保持不变.当用与昼夜光照颠倒的周期(D-L-D)作实验时,所有被检测的细胞都反映出夜间的放电活性受到了不同程度的抑制.     

松果体与肿瘤

长期以来,松果体被视为一个无特殊功能的残余器官。Lerner(1958)从牛的松果体提取出一种能使蛙皮肤颜色变浅的活性物质——5-甲氧-N-乙酰色胺(5-methoxy-N-acetyltrypt-amine),称为抗黑变素或黑色紧张素(melatonin,MLT)。Giarman等(1960)从人的松果体内发现有较多的血清紧张素(serotonin或5-HT)以及能将这类吲哚胺转化为MLT的各种酶。后来,又陆续从哺乳动物的松果体分离出具有多种生物学活性的多肽类物质(如精氨酸催产素vasotocin等)。实验证明:松果体的分泌或组织提取物对大脑、丘脑下部、垂体、性腺、甲状腺、肾上腺皮质等都有作用;它接受外环境的光、声、温度、嗅以及时令季节变化     

荒漠沙蜥松果体褪黑激素含量的季节性变化

应用高效液相色谱法(HPLC)-UV检测了不同季节荒漠沙蜥(Phrynocephalus przewalskii)松果体内褪黑激素的含量.结果显示,其高峰值发生在春季,为1 017±209 pg/pineal.低峰值出现在冬季(实验室内冬眠,2～4℃),为355±68.5 pg/pineal,秋季的含量(735±133.7 pg/pineal)高于夏季的含量(597±94.9 pg/pineal).表明荒漠沙蜥松果体褪黑激素含量呈现明显的年周期节律并与光周期和生殖周期的年节律基本相符.     

Light and electron microscopic studies on the pineal tract of rainbow trout, Salmo gairdneri.

The pineal tract of rainbow trout from the pineal end vesicle to the posterior commissure was studied by light and electron microscopy. Five types of nerve fibres (photoreceptor basal process, ganglion cell dendrite, electron-lucent fibre and synaptic vesicles, myelinated and unmyelinated axons) and two modes of synapses (photoreceptor basal process ganglion cell dendrite and axon terminal with synaptic vesicles-photoreceptor basal process synapses) are distinguishable in the proximal region of end vesicle. The two distinct synaptic associations with the photoreceptor basal process suggest two different (excitatory and inhibitory) control of pineal sensory activity. At the distal portion of stalk about two thousand nerve fibres converge into dorsal and ventral bundles. Posterior to the habenular commissure several small branches run out laterally from the ventral bundles to the basal margin of the ependyma, but not into the habenular commissure. The dorsal bundle passes through the dorsal side of the subcommissural organ and runs ventral to the posterior commissure. The pineal tract is composed of unmyelinated axons, electron-lucent nerve fibres and myelinated axons. The number of fibres increases throughout the stalk and reaches the maximum number at the opening of pineal lumen to IIIrd ventricle, however, the number of fibres then decreases through the subcommissural organ and posterior commissure. This increase and decrease of nerve fibres suggest the continuous participation of axonal fibres of pineal nerve cells and the ramification or branching of pineal tract, respectively.     

Morphology of the pineal organ in the salamander Ensatina eschscholtzi

The pineal organ of Ensatina eschscholtzi, a terrestrial and secretive species of salamander of the family Plethodontidae, is a photoreceptive structure lying on the dorsal surface of the diencephalon. The pineal is flattened with a broad lumen and consists of three cell types: photoreceptors, supportive cells, and neurons. Pineal photoreceptors are typical vertebrate photoreceptors and possess outer segment formations which, however, are frequently contorted and disorganized. Sloughing of apical portions of outer segments and vesiculation along the lateral edges of outer segment membrane disks are consistently observed and presumed to represent mechanisms of outer segment membrane recycling. Photoreceptors have basal processes which synapse with neural dendrites. Synapses between photoreceptor basal processes are occasionally observed. All synapses are characterized by synaptic ribbon structures of variable number, size, and configuration. Dense-core vesicles are occasionally observed mingled with clear synaptic vesicles within photoreceptor basal processes. Supportive cells within the pineal function in phagocytosis and recycling of shed outer segment membrane material, and neurons are localized at the lateral margins of the organ. The latter send axons into the ipsilateral side of the dorsal diencephalon. The pineal organ of Ensatina shows marked variation in overall size (cell total), cell type proportions, absolute neuron number, and ratio of photoreceptor number to neuron number for individual pineals. None of these morphological parameters is correlated with body size, sex, or season, and it is assumed that such variability represents significant variation in photosensory capabilities. It is suggested that the pineal organ of Ensatina is a partially degenerate photoreceptive structure.     

The pineal-paraphyseal complex of sea turtles. I. Light microscopic description

The pineal-paraphyseal complex of sea turtles is an impressively large structure which projects dorsally and anteriorly above the prosencephalon. The complex was examined by light microscopy in several age classes of green sea turtles (Chelonia mydas) and from juvenile loggerhead turtles (Caretta caretta). The paraphysis is extensively fused to the distal portion of the pineal body, suggesting an interrelated function for these two tissues. No duct or canal was observed connecting the pineal lumen to the third ventricle. Two pineal cell types are described which appear to correspond to the neuroglial supportive cells and the secretory rudimentary photoreceptor cells of other amniotic vertebrates. A possible luminal secretion in the form of apical protrusions is produced by the latter cell type. No typical photoreceptive outer segments were observed.     

Morphology of the pineal complex in seven species of lanternfishes (Pisces: Myctophidae)

The morphology of the pineal complex was compared in seven species of lanternfishes (family Myctophidae) using both light and electron microscopes. On the basis of compactness of the pineal end-vesicle and presence or absence of a dorsal sac, the species in this study were divided into two groups. This grouping seems to correlate well with current views on the phylogenetic relationships among these fishes. Receptor cells and supportive cells are described in the pineals of all species examined. The deepest-dwelling of the forms studied, Parvilux ingens, showed a significant increase in the mean number of lamellar membranes in the outer segments of the receptor cells and a higher convergence ratio of receptor cells to ganglion cells as compared to the shallow-dwelling form Tarletonbeania crenularis. Accordingly it is suggested that the pineal of P. ingens is more photosensitive. Additional differences among species were found in the ultrastructure of the supportive cells. Dorsal sacs were absent in the three shallowest-occurring myctophids studied. In those species with a dorsal sac, its close association with the pineal-end-vesicle suggests a functional relationship between the two structures.     

The pineal complex: a morphological and immunohistochemical comparison between a tropical (Paracheirodon axelrodi) and a subtropical (Aphyocharax anisitsi) characid species

Cardinal neon Paracheirodon axelrodi and bloodfin tetra Aphyocharax anisitsi are two species of characids with high trade value as ornamental fish in South America. Although both species inhabit middle water layers, cardinal neon exhibits a tropical distribution and bloodfin tetra a subtropical one. In this work, we carried out an anatomical, histological and immunohistochemical study of the pineal complex of P. axelrodi and A. anisitsi. In both species, the pineal complex consisted of three components, the pineal and parapineal organs and the dorsal sac (DS). The pineal organ was composed of a short, thin pineal stalk (PS), vertically disposed with respect to the upper surface of the telencephalon, and a pineal vesicle (PV), located at the distal end of the PS and attached to the skull by connective tissue. The pineal window (PW), a site in the skull where the luminal information accesses the pineal organ, appeared just above the latter structures. In the epidermis of P. axelrodi's PW, club cells were identified, but were not observed in the epidermis of A. anisitsi's one. With respect to the DS, it appeared to be folded on itself, and was bigger and more folded in A. anisitsi than in P. axelrodi. Immunohistochemical assays revealed the presence of cone opsin‐like and rod opsin‐like photoreceptor cells in the PS and PV. These results provide a first insight into the morphological assembly of the pineal complex of both species, and contribute to a better understanding of the integration and transduction of light stimuli in characids. J. Morphol. 277:1355–1367, 2016. © 2016 Wiley Periodicals, Inc.     

A comparative study of the pineal complex in the deep-sea fishes Bathylagus wesethi and Nezumia liolepis

Summary The pineal complexes of two deep-sea fishes, Bathylagus wesethi (family Bathylagidae) and Nezumia liolepis (family Macrouridae), were studied with both light and electron microscopy. Receptor and supportive cells were identified in the pineals of both species. The presence of receptor cells suggests that the pineals function in photoreception. Ganglion cells could be identified only in B. wesethi. A dorsal sac and a paraphysis were found in B. wesethi; both structures are absent in N. liolepis.Several trends were found when the results of this study were compared with those of a study on the pineal complex of another deep-sea fish, the myctophid Triphoturus mexicanus (McNulty and Nafpaktitis, 1976). Two of these trends, which are correlated with the vertical distributions of the species studied, suggest an increase in the photosensitivity of the pineals. These are: 1) an increase in the average number of outer segment lamellar membranes per receptor cell, and 2) an increase in the ratio of receptor cells to nerve fibers in the pineal stalks.A functional relationship between the dorsal sac, paraphysis, and pineal central lumen was suggested. The relationship may involve secretory activities.     

The Structure and Development of the Pineal Complex in the Lanternfish Triphoturus mexicanus (Family Myctophidae)

The pineal complex of the lanternfish Triphoturus mexicanus was studied by light and electron microscopy. Receptor, supportive and ganglion cells were identified in the pineal end-vesicle. The presence of receptor cells and the prominent pineal window strongly suggest a photoreceptive function. Numerous unmyelinated nerve fibers were also found in the end-vesicle. These converge to form part of the pineal stalk. Two kinds of cells (Types I and II) were distinguished in the dorsal sac, which is very well developed. Type I cells are non-ciliated ependymal cells and contain large parcels of glycogen. Type II cells contain large lipidlike inclusions and a distinct band of filaments around the entire periphery of the cell. Receptor cells appear very early in the development of T. mexicanus. They seem to originate from ependymal cells lining the roof of the third ventricle.     

The morphology and histology of the pineal organ in roach, Rutilus rutilus (L.)

The pineal organ in the roach, Rutilus rutilus (L.), is covered by a semi-transparent area, the pineal window. Beneath this the pineal is attached to a long robust stalk, lying just under the parietal bone. The pineal is attached to the brain through the dorsal sac. Three cell types have been identified histologically. These are the sensory cells, supporting cells and the ganglia cells. The inner segment of the sensory cells respond to PAS and AF staining, while the remaining cells respond to Orange G, LG, or Acid Fuchsin. The evidence suggests that the roach pineal may have a dual photosensory and glandular function.     

Photoreceptor cells and neural elements with long axonal processes in the pineal organ of the lamprey,Lampetra japonica,identified by use of the horseradish peroxidase method

Summary Horseradish peroxidase (HRP) was applied to the transected end of the pineal tract of the lamprey, Lampetra japonica. Distinct reaction products of HRP were observed in 2 types of cell other than ganglion cells. The first type of cell protrudes a knob-like process into the pineal lumen. This type of cell was clearly identified by electron microscopy as a photoreceptor cell; its outer segment was connected to the ellipsoid through a sensory cilium. The other type of cell was located among photoreceptor and supporting cells. The processes of these cells were thin and slender, and they obviously did not represent photoreceptor, supporting, or conventional ganglion cells. The present results indicate that, in the lamprey, some of the photoreceptor cells of the pineal organ project their axon-like processes toward the posterior commissure, but that there is also another type of cell displaying long axonal projections. HRP-containing cells were distributed randomly over the pineal organ and were occasionally also observed in the parapineal organ.