5-羟色胺在粘虫视叶中的分布

【目的】解剖分析粘虫Mythimna separata成虫视叶的结构,研究5-羟色胺(5-hydroxytryptamine,5-HT)在视叶中的分布。【方法】采用组织包埋切片技术和免疫组织化学方法,使用突触蛋白抗体标记粘虫成虫视叶内神经髓结构,用抗5-HT血清标记5-HT;利用激光共聚焦扫描显微镜照相获取数码图像,利用图形分析软件识别神经髓结构及进行细胞体群分组与计数。【结果】粘虫成虫的视叶由视神经节层、视髓、副视髓、视小叶和视小叶板5个神经髓结构组成。免疫染色显示粘虫视叶内具有5-HT,每个视叶内约具有40个5-HT免疫标记的细胞体,这些细胞体分为3个细胞体群,位于视髓前方或腹面的内侧。视叶内所有的神经髓结构均含有5-HT免疫标记神经纤维。视神经节层的5-HT免疫标记神经纤维来自视叶的切向神经元,视髓的5-HT免疫标记神经纤维主要来自视叶的切向神经元、远心神经元和无长突神经元。视髓呈明显分层现象,主要分为3层,其中中间一层5-HT免疫标记神经纤维较密集。副视髓存在少量的5-HT免疫标记神经纤维。视小叶和视小叶板中的5-HT免疫标记神经纤维来自远心神经元,分为明显的2层,其中有少量神经纤维投射至视髓,将视小叶、视小叶板和视髓连接起来。【结论】粘虫视叶中广泛分布着5-HT免疫标记神经纤维。该研究结果为进一步研究5-HT在视觉机制中的作用奠定一定的解剖学基础。     

桔小实蝇视叶结构特征及5-羟色胺能神经元的分布

桔小实蝇是重要的果蔬害虫,它对不同颜色的光表现出不同的趋性。为了明确其视觉感受的结构基础,本研究采用免疫组织化学染色技术结合激光共聚焦成像分析了桔小实蝇成虫视叶内神经髓结构组成和体积大小,并利用5-羟色胺(5-hydroxytryptamine,5-HT)抗体标记了视叶内5-羟色胺能神经元,研究了其在视叶内的分布特征及细胞体数量。结果表明,桔小实蝇成虫的视叶由视神经节层、视髓、副视髓、视小叶和视小叶板5个神经髓结构组成,其中雌成虫的视髓相对体积极显著的大于雄虫的视髓相对体积。桔小实蝇每个视叶中包含12个5-HT能神经元细胞体,位于视髓的腹内侧,副视髓的前方。视叶5个神经髓区均含5-HT能神经纤维,但它们的神经纤维来自不同的神经元。对视叶神经髓结构及5-HT能神经元分布特征的研究将为未来构建桔小实蝇视觉神经通路和阐明5-HT对视觉感受的调控机制奠定解剖学基础。     

异色瓢虫视觉系统中5-HT阳性神经元的分布(英文)

本文运用树脂石蜡(Colophony-Paraffin, CP;专利号: ZL98125709·7)组织包埋切片技术,结合免疫组织化学链酶菌抗生物素蛋白-过氧化物酶(Streptavidin-Peroxidase , SP)双染法,对异色瓢虫视觉系统中5-羟色胺(5-HT)能神经元的分布进行了初步研究。结果显示,异色瓢虫视觉系统的结构及5-HT免疫反应系统相对比较特殊。5-HT阳性神经元胞体数目较少,染色显著,并聚集成群。根据胞体定位、细胞形态及轴突走向,可大体分为5群,其中包括1群呈弱反应的光感细胞。5-HT阳性膨大纤维支配所有的视神经纤维网,并呈柱状或分层排列模式。结果表明5-HT作为经典的神经递质在昆虫的视觉信息处理过程中可能发挥重要的调节作用,且主要以远距离的广域神经调节模式为主,并在特定区域和GABA有伴随现象。此外,昆虫视觉系统中5-HT的含量还可能与其明暗适应的生理调节方式具有相关性[动物学报51 (5) : 912 -918 , 2005]。     

异色瓢虫视觉系统中5-HT阳性神经元的分布

本文运用树脂石蜡（Colophony-Paraffin,CP;专利号：ZL98125709．7）组织包埋切片技术,结合免疫组织化学链酶菌抗生物素蛋白一过氧化物酶（Streptavidin-Peroxidase,SP）双染法,对异色瓢虫视觉系统中5-羟色胺（5-HT）能神经元的分布进行了初步研究。结果显示,异色瓢虫视觉系统的结构及5-HT免疫反应系统相对比较特殊。5-HT阳性神经元胞体数目较少,染色显著,并聚集成群。根据胞体定位、细胞形态及轴突走向,可大体分为5群,其中包括1群呈弱反应的光感细胞。5-HT阳性膨大纤维支配所有的视神经纤维网,并呈柱状或分层排列模式。结果表明5-HT作为经典的神经递质在昆虫的视觉信息处理过程中可能发挥重要的调节作用,且主要以远距离的广域神经调节模式为主,并在特定区域和GABA有伴随现象。此外,昆虫视觉系统中5-HT的含量还可能与其明暗适应的生理调节方式具有相关性[动物学报51（5）：912—918,2005]。     

迷蛱蝶属及相关物种细胞色素b基因序列及其分子系统学研究

迷蛱蝶属Mimathyma隶属于蛱蝶科Nymphalidae闪蛱蝶亚科Apaturinae,该属所包含的种类复杂,其分类学地位存在争议.本文对迷蛱蝶属、闪蛱蝶属Apatura和带蛱蝶属Athyma7个种共19个个体的线粒体DNA细胞色素b基因部分序列进行测定分析,并以花斑螯蛱蝶Charaxes kahruba (Moore)作为外群用PAUP软件构建MP和NJ分子系统树.结果显示迷蛱蝶Mimathyma chevana(Moore)、夜迷蛱蝶Mimathyma nycteis(Ménétriès)、白斑迷蛱蝶Mimathyma schrenckii (Ménétriès)和环带迷蛱蝶Mimathyma ambica Kollar形成1个聚类簇,支持Moore将这4个种由闪蛱蝶属移出并建立迷蛱蝶属的观点.同时,尽管迷蛱蝶在形态上与该属其余3种相似,但研究发现聚类簇Ⅰ中夜迷蛱蝶、白斑迷蛱蝶和环带迷蛱蝶首先相聚,然后再与迷蛱蝶聚在一起,表明迷蛱蝶与这3种亲缘关系较远.此外,本文的研究结果还显示迷蛱蝶属与闪蛱蝶属关系密切,而与带蛱蝶属的关系较远.     

双斑蟋复眼和视叶的显微结构

【目的】为探索昆虫视觉信号处理的重要神经结构,详细观察和描述了直翅目(Orthoptera)蟋蟀科(Gryllidae)代表性昆虫双斑蟋Gryllus bimaculatus De Geer复眼和视叶的组织学结构特征。【方法】利用扫描电镜技术和组织学切片技术,观察分析了30只双斑蟋的复眼和视叶组织学结构。【结果】双斑蟋复眼约有3400个小眼,均为六边形结构,小眼间隙内分布有机械感受器——感觉毛和钟形感受器。每个小眼均由角膜、晶锥、感杆束、6个网膜细胞及基膜等构成。视叶呈两个扇形结构,由三大神经纤维网构成,分别为神经节层、外髓、内髓。【结论】双斑蟋复眼表面具有少量感觉毛和钟形感受器,每个小眼均由角膜、晶锥、感杆束、6个网膜细胞及基膜等构成,属并列像眼,视叶由三大神经纤维网构成。     

猫下丘中央核5-HT、P物质和星形胶质细胞年龄相关变化

目的比较研究青年猫与老年猫下丘中央核(CIC)5-羟色氨(5-HT)、P物质(SP)能神经元及星形胶质细胞年龄性变化,探索老年个体听力下降的神经机制。方法 Nissl染色显示下丘神经元,免疫组织化学ABC法显示5-HT、SP和胶质纤维酸性蛋白(GFAP)免疫反应(immunoreactive,IR)细胞。光镜下观察、拍照,对神经元和5-HT、SP及GFAP免疫反应细胞分别计数并换算成密度,测量其IR细胞直径取平均值,以及它们的阳性反应平均灰度值。结果 5-HT-IR、SP-IR和GFAP-IR细胞、阳性纤维及其终末在青年猫及老年猫下丘中央核均有分布。与青年猫相比,老年猫下丘中央核5-HT密度均显著下降(P<0.01),胞体直径明显减小(P<0.01),阳性反应明显减弱(阳性反应强度与灰度值呈负相关),SP-IR神经元和星形胶质细胞密度却显著增大,阳性反应显著增强。结论在衰老过程中猫下丘神经元尤其是5-HT能神经元有显著丢失现象,提示5-HT能神经元显著减少导致下丘听觉信息传递功能减弱,可能引起老年个体听觉功能衰退的重要原因;SP能神经元和星形胶质细胞密度显著增大,可能起到延缓衰老的作用。     

脊髓和脊神经节原代分离培养中GABA能神经元的形态观察

选用12—14天胚胎小鼠(C 57 BL/6J),取脊髓及脊神经节原代培养。观察神经元的发育并用GABA抗血清、PAP方法显示GABA能神经元。脊髓神经元呈各种形态大小,随着培养的进行它们的突起和胞体不断生长;脊神经节细胞有不同大小,其体积在培养中保持恒定。随着神经元的逐渐成熟,它们的核质比不断增大。GABA免疫细胞化学阳性脊髓神经元大小不等,可分为两类:1.突起和胞体阳性,核不着色而核仁着色;2.只在突起和细胞膜上有阳性反应而胞体及核为阴性(可能为GABA摄取的结果)。有不同大小的脊神经节细胞呈阳性反应,其胞体及核仁着色而核呈阴性反应。证实了培养条件下处于胚胎发育阶段的阳性脊神经节细胞的存在。     

基于线粒体CO Ⅰ基因的闪蛱蝶亚科系统发育关系研究

测定了重要林业害虫闪蛱蝶亚科Apaturinae 11属17种蝶类的线粒体细胞色素氧化酶Ⅰ的部分序列,并结合由GenBank下载的该亚科4种蝶类的相应序列进行分析,探讨了闪蛱蝶亚科各属间的系统发育关系。以玉杵带蛱蝶Athymajina,白斑眼蝶Penthema adelma,忘忧尾蛱蝶Polyura nepenthes和白带螯蛱蝶Charaxes bernardus作为外群,采用PAUP4.0b4a软件构建了闪蛱蝶亚科的MP和NJ分子系统树。虽然COI基因数据中第3位点的转换替换已达饱和,但由于这些位点含有大量系统发育信息,因而在数据统计分析时并没有将这些位点删除。同时通过对各分枝稳定性的比较,研究在简约分析中不同转换/颠换加权方式对假定所有特征具有相同权重的影响。分子系统树显示:NJ和不同转换/颠换加权方式下构建的MP系统树中闪蛱蝶亚科均有4个主要的聚类簇,该亚科系统树中存在许多置信度高且稳定的分枝,同时也存在一些因分枝置信度低且不稳定而使其分类地位不能确定的类群。在所构建的系统树中,由分子数据得到的蛱蝶亚科系统发育关系与传统分类学的基本一致,其中迷蛱蝶属Mimathyma为单系群;累积蛱蝶Lelecella limenitoides为明窗蛱蝶Dilipa fenestra的姐妹群且支持二者关系的置信度很高;支持将白斑迷蛱蝶Mimathyma schrenckii,迷蛱蝶M.chevana,夜迷蛱蝶M.nycteis,栗铠蛱蝶Chitoria subcaerulea,黄带铠蛱蝶C.fasciola,铂铠蛱蝶C.pallas,and银白蛱蝶Helcyra subalba等物种由闪蛱蝶属中移出的修订。     

蟋蟀视觉系统的解剖结构与生理机能

蟋蟀视觉系统由单眼、复眼、视叶三部分组成。蟋蟀的单眼为背单眼,由角膜、角膜生成细胞、视网膜等组成,是提高昆虫复眼所感知的视觉刺激的兴奋水平部位;复眼是最主要的视觉器官,由角膜、晶锥、感杆束和网膜细胞、基膜组成,是光电转导和视觉级联反应的中心;视叶由神经节层、外髓和内髓组成,是视觉神经系统的中心。     

Distribution of GABA-like immunoreactive neurons in the optic lobes of Periplaneta americana

Summary Specific antisera against protein-conjugated -aminobutyric acid (GABA) were used in immunocytochemical staining procedures to study the distribution of the putative GABA-like immunoreactive neurons in the optic lobes of Periplaneta. GABA-like immunoreactive structures are evident in all three optic neuropil regions. Six different populations of GABAergic neurons, whose perikarya are grouped around the medulla, are found within the optic lobe. The number of these immunoreactive cells varies greatly and corresponds to the number of ommatidia of the eye. In the proximal part of the lamina, a coarse network of GABA-positive fibres is recognizable. These are the processes of large field tangential cells whose fibres pass through the distal surface of the medulla. A second fibre population of the lamina is made up of the processes of the centrifugal columnar neurons whose perikarya lie proximally to the medulla. The medulla contains 9 layers with GABAergic elements of variable immunoreactivity. Layers 1, 3, 5, 7 and 9 exhibit strong labelling, as a result of partial overlapping of the processes of centrifugal and centripetal columnar neurons, tangential fibres and/or lateral processes of perpendicular fibres and (possibly) processes of amacrines. A strong immunoreactivity is found in the proximal and distal layers of the lobula.     

Insect optic lobe neurons identifiable with monoclonal antibodies to GABA

Summary Five monoclonal antibodies aginst GABA were tested on glutaraldehyde fixed sections of optic lobes of three insect species, blowflies, houseflies and worker bees. The specificity of these antibodies was analyzed in several tests and compared with commercially available anti-GABA antiserum.A very large number of GABA-like immunoreactive neurons inncrvate all the neuropil regions of these optic lobes. Immunoreactive processes are found in different layers of the neuropils. The immunoreactive neurons are amacrines and columnar or noncolumnar neurons connecting the optic lobe neuropils. In addition some large immunoreactive neurons connect the optic lobes with centers of the brain.Some neuron types could be matched with neurons previously identified with other methods. The connections of a few of these neuron types are partly known from electron microscopy or electrophysiology and a possible role of GABA in certain neural circuits can be discussed.     

Insect optic lobe neurons identifiable with monoclonal antibodies to GABA

Five monoclonal antibodies against GABA were tested on glutaraldehyde fixed sections of optic lobes of three insect species, blowflies, houseflies and worker bees. The specificity of these antibodies was analyzed in several tests and compared with commercially available anti-GABA antiserum. A very large number of GABA-like immunoreactive neurons innervate all the neuropil regions of these optic lobes. Immunoreactive processes are found in different layers of the neuropils. The immunoreactive neurons are amacrines and columnar or noncolumnar neurons connecting the optic lobe neuropils. In addition some large immunoreactive neurons connect the optic lobes with centers of the brain. Some neuron types could be matched with neurons previously identified with other methods. The connections of a few of these neuron types are partly known from electron microscopy or electrophysiology and a possible role of GABA in certain neural circuits can be discussed.     

GABA-immunohistological observations, at the electron-microscopical level, of the neurons of isthmic nuclei in chicken, Gallus domesticus

Following a demonstration of Golgi-impregnated neurons and their terminal axon arborization in the optic tectum, the neurons of the nucleus parvocellularis and magnocellularis isthmi were studied by means of postembedded electron-microscopical (EM) γ-aminobutyric acid (GABA)-immunogold staining. In the parvocellular nucleus, none of the neuronal cell bodies or dendrites displayed GABA-like immunoreactivity in EM preparations stained by postembedded GABA-immunogold. However, numerous GABA-like immunoreactive and also unlabeled terminals established synapses with GABA-negative neurons. GABA-like immunoreactive terminals were usually found at the dendritic origin. Around the dendritic profiles, isolated synapses of both GABA-like immunoreactive and immunonegative terminals established glomerulus-like structures enclosed by glial processes. All giant and large neurons of the magnocellular nucleus of the isthmi displayed GABA-like immunoreactivity. Their cell surface was completely covered by GABA-like immunoreactive and unlabeled terminals that established synapses with the neurons. These neurons are thought to send axon collaterals to the parvocellular nucleus; their axons enter the tectum opticum. The morphological characteristics of neurons of both isthmic nuclei are like those of interneurons, because of their numerous axosomatic synapses with both asymmetrical and symmetrical features. These neurons are not located among their target neurons and exert their modulatory effect on optic transmission in the optic tectum at a distance.     

Immunoreactivity of Glutamic Acid Decarboxylase (GAD) Isoforms in the Central Nervous System of the Barn Spider,Araneus cavaticus

The γ‐aminobutyric acid (GABA) has long been considered as an inhibitory neurotransmitter in the central nervous system (CNS) of both vertebrates and arthropods. Since the glutamic acid decarboxylase (GAD) has a restricted tissue distribution and catalyzes the conversion of L‐glutamate to GABA, immunoreactivity of GAD isoforms can reveal distribution of GABAergic neurons in the CNS. In the CNS of the spider Araneus cavaticus, immunoreactivity of GAD isoforms can be detected in the optic lobes including neurons and neuropiles of the supraesophageal ganglia. Strong GAD‐like immunoreactive cell bodies are concentrated in two bilaterally symmetric cell clusters of the protocerebrum. Some intrinsic cell bodies near the central body also show strong immunoreactivity. However, the intrinsic nerve masses and some of the longitudinal and transverse tracts within the supraesophageal ganglion are only lightly labelled, and the fibers transverse the hemisphere and the central fibrous masses are not labelled. Among the three basic types of cell bodies surrounding the central body, several clusters of the Type‐C cells show strong GAD‐like immunoreactivity, however both of the Type‐A and Type‐B cells are not labelled at all.     

Immunocytochemistry of GABA and glutamic acid decarboxylase in the thoracic ganglion of the crab Eriphia spinifrons

We have used specific antisera against protein-conjugated -aminobutyric acid (GABA) and rat-brain glutamic acid decarboxylase (GAD) in immunocytochemical preparations to study the distribution of putatively GABAergic neurons in the fused thoracic ganglion of the crab Eriphia spinifrons. In the thoracic neuromeres, about 2000 neurons with somata arranged in clusters or located singly in the cell cortex exhibited both GABA-like and GAD-like immunoreactivity. In addition, more than a hundred cells showed only GABA-like immunoreactivity. Fibrous immunoreactive staining to GAD and GABA was distributed throughout the neuropil of the thoracic ganglion, and several fiber tracts contained immunoreactive processes. Sets of serially homologous neurons exhibited GABA-like and GAD-like immunoreactivity in the thoracic neuromeres. Especially prominent were one medial and four ventro-lateral clusters of somata, together with thirteen individually recognized cells in each neuromere. Six of these cells in the ventro-medial cell cortex may be the somata of inhibitory motoneurons. The leg nerves contained three immunoreactive fibers, corresponding to the previously described common inhibitory motoneuron and the two specific inhibitors. The results present further evidence for GABA being the neurotransmitter of all inhibitory leg motorneurons, and suggest its presence and role as a neurotransmitter in a considerable number of interneurons in the thoracic ganglion of the crab.     

Somatostatin-, calcitonin gene-related peptide, and gamma-aminobutyric acid-like immunoreactivitity in the frog lumbosacral spinal cord: distribution and effects of sciatic nerve transection

Using immunohistochemistry and optical densitometry, somatostatin (SOM), calcitonin gene-related peptide (CGRP), and gamma-aminobutyric acid (GABA) were investigated in the lumbosacral spinal cord of the frog Rana catesbeiana after sciatic nerve transection. In control animals, the densest network of the SOM-, CGRP- and GABA-like immunoreactive fibers was located in the dorsal part of the lateral funiculus. SOM and GABA-like fibers were found in the dorsal terminal field and in the mediolateral band. The latter region showed CGRP and SOM-like immunoreactive cell bodies. SOM- and GABA-like immunoreactive neurons also occurred around the cavity of the central canal, and other GABA-like fibers were found in the ventral terminal field. While the ventral horn showed scarce somatostatin-like fibers, the putative motoneurons were immunoreactive for the two peptides investigated and GABA, but only a few SOM- and GABA-like fibers occurred in the ventral funiculus. After axotomy, GABA-like immunoreactivity decreased in the dorsal part of the lateral funiculus on the same side of the lesion. The other regions remained labeled. These changes were observed at 3 days following axonal injury and persisted at 5, 8 and 15 days. There was no significant difference in the pattern of CGRP- and SOM- immunoreactivity between the axotomized and the control sides. These results are discussed in relation to the effects of the peripheral axotomy on GABA, SOM, and CGRP expression in vertebrates, emphasizing the use of frogs as a model to study the effects of peripheral nerve injury.     

Evidence for the presence of serotonin in Mysidacea (Crustacea,Peracarida) as revealed by fluorescence immunohistochemistry

In crustaceans, serotonin (5-HT) exerts a wide range of physiological actions on many tissues. However, 5-HT has not been detected to date in Mysidacea (Crustacea, Peracarida). We have investigated the presence of 5-HT in the brain and the eyestalks of two Mysida (Leptomysis lingvura, Hemimysis margalefi) and one Lophogastrida (Lophogaster typicus) species by using the immunohistofluorescence technique. 5-HT-like immunopositive areas exhibit a similar pattern in the three species. 5-HT-like immunostaining is present in the retinular photosensitive cells, except in the deep-living species L. typicus. 5-HT-like cell bodies and fibres are observed in the lamina ganglionaris and in the three medullae. In the sinus gland, only 5-HT-like endings are detected. In the eyestalks, 5-HT-like fibres detected in the optic tract link with the protocerebrum, in which 5-HT-like somata and their extensions are found. Some neurones are detected in the anterior median cell cluster, in the protocerebral bridge and in the central body. In the deutocerebrum, the paracentral lobes are connected by immunoreactive fibres that run along the deutocerebral commissure. The glomeruli of the olfactory lobes exhibit strong diffuse immunostaining. Beside and in the median part of the deutocerebrum, at least two large serotoninergic neurones project their axons into the olfactory lobe cell cluster. Immunoreactive fibres are also found in the antennular neuropiles. Our results demonstrate the presence of 5-HT-like cell bodies and fibres in Mysidacea. The distribution patterns of the 5-HT immunoreactivity found herein are compared with those of other peracarids and decapods.     

Immunocytochemical localization of GAD isoforms in the CNS ganglia of the cobweb spider,Achaearanea tepidariorum

Glutamic acid decarboxylase (GAD) is an enzyme that catalyzes the decarboxylation of glutamate to γ‐aminobutyric acid (GABA) and CO₂. It has been discovered that the GAD has a restricted tissue distribution and it is highly expressed in the cytoplasm of GABAergic neurons in the CNS where GABA is used as a neurotransmitter. We have examined the microstructure of ganglionic neurons and nerves arising from the CNS and describe here the immunocytochemical localization of GAD isoforms to reveal the ecophysiological significance of GABA for the web‐building spider's behavior. In the CNS of the cobweb spider, Achaearanea tepidariorum, immunocytochemical localization of GAD isoforms can be detected in the neurons and neuropiles of the optic lobes. In addition, GAD‐like immunoreactive cell bodies are observed at the intrinsic cell bodies near the central body and the symmetric cell clusters of the protocerebrum. However, the fibrous masses within the protocerebral ganglion are not labeled at all. Based on its interconnection with other regions of the CNS, our findings suggest that the central body in the web‐building spider may act as an association center as well as a visual center.     

Organization of local interneurons in optic glomeruli of the dipterous visual system and comparisons with the antennal lobes

The lateral protocerebrum of the fly's brain is composed of a system of optic glomeruli, the organization of which compares to that of antennal lobe glomeruli. Each optic glomerulus receives converging axon terminals from a unique ensemble of optic lobe output neurons. Glomeruli are interconnected by systems of spiking and nonspiking local interneurons that are morphologically similar to diffuse and polarized local interneurons in the antennal lobes. GABA-like immunoreactive processes richly supply optic glomeruli, which are also invaded by processes originating from the midbrain and subesophageal ganglia. These arrangements support the suggestion that circuits amongst optic glomeruli refine and elaborate visual information carried by optic lobe outputs, relaying data to long-axoned neurons that extend to other parts of the central nervous system including thoracic ganglia. The representation in optic glomeruli of other modalities suggests that gating of visual information by other sensory inputs, a phenomenon documented from the recordings of descending neurons, could occur before the descending neuron dendrites. The present results demonstrate that future studies must consider the roles of other senses in visual processing.