P物质受体在大鼠纹状体边缘区内的表达

我们以前的工作观察到纹状体边缘区内有密集的P物质纤维及终末分布,本用原位杂交和免疫组织化学方法研究了大鼠纹状体边缘区内P物质受体（SPR）的表达及分布,原位杂交结果发现P物质mRNA阳性杂交信号在纹状体内的分布不均匀,尾壳核内只有少量中等大小的阳性胞体,苍白球内只有少量较大的阳性胸体,而在尾壳核和苍白球之间的边缘区部位则可见许多中等大小的梭形阳性神经元胞体,并呈现密集的带关分布。免疫组织化学结果观察到P物质阳性神经元胞体在纹状体内的分布与原位杂交结果一致。推测大鼠纹体边缘区内可以合成P物质受体,具有接受和整合P物质神经递质的功能,推测边缘区内SPR神经元可能对SP递质的接受、调节有重要作用。     

大鼠全脑缺血后纹状体边缘区内降钙素基因相关肽和谷氨酸脱羧酶表达的变化

为研究全脑缺血再灌流后纹状体边缘区内降钙素基因相关肽（CGRP）和谷氨酸脱羧酶（GAD）等神经递质的表达变化。在两侧颈总动脉和椎动脉结扎造成的大鼠全脑缺血模型上,用免疫组织化学方法观察纹状体边缘区内CGRP和GAD等免疫阳性反应的分布,结果显示正常大鼠脑纹状体内有CGRP和GAD阳性神经纤维的分布,全脑缺血再灌流1天后,边缘区中的CGRP免疫阳性反应逐渐增强,在第5天时达到最高峰,全脑缺血再灌流后1天,可见边缘区部位的GAD免疫阳性反应增强,但以后边缘区内的GAD免疫反应阳性物质逐渐减少,缺血再灌流5天后,边缘区中GAD免疫阳性反应的表达基本消失。研究结果表明全脑缺血后边缘区中的CGRP反应逐渐增强,这种变化可能和脑缺血后动物的学习记忆能力下降有关。     

催产素、精氨酸加压素、促肾上腺皮质激素释放激素、神经肽Y、神经降压肽、P物质及亮氨酸脑啡肽免疫阳性纤维在大鼠结合臂旁核的分布

应用免疫细胞化学 ABC 技术观察了催产素、精氨酸加压素、促肾上腺皮质激素释放激素、神经肽 Y、神经降压肽、P 物质及亮氨酸脑啡肽免疫反应阳性纤维在大鼠结合臂旁核中的分布。催产素阳性纤维稀少,分布于腹外侧亚核、外外侧亚核、背外侧亚核及外外侧亚核与背外侧亚核之间的移行区。加压素阳性纤维亦甚为稀少,分布于腹外侧亚核、背外侧亚核、外外侧亚核与极外侧亚核.促肾上腺皮质激素释放激素阳性纤维分布于尾侧部臂旁核腰区、外外侧亚核腹内侧部、极外侧亚核、背外侧亚核、中央外侧亚核、内外侧亚核及臂旁内侧核。神经肽 Y 阳性纤维大多为串珠状的终末祥结构,分布于尾侧部腹外侧亚核、背外侧亚核、外外侧亚核背外侧部及外内侧亚核,在上外侧亚核、结合臂背内侧端背侧及臂旁内侧核腹侧部也有少量分布.神经降压肽阳性纤维分布于尾侧部臂旁核腰区、背外侧亚核、背外侧亚核与外外侧亚核之间的移行区、外外侧亚核、外内侧亚核及中吻部臂旁内侧核腹侧部。P 物质及亮氨酸脑啡肽阳性纤维分布于所有的臂旁外侧核诸亚核及外内侧亚核。     

大鼠面部伤害性刺激后纹状体边缘区内原癌基因c-fos和NOS的表达

为了研究纹状体边缘区和痛觉的关系,用c-fos和NADPH－d双标记方法研究了大鼠面部伤害性刺激后c-fos蛋白（Fos）和NOS在纹状体边缘区的表达。面部伤害性刺激后30分钟,边缘区中即出现Fos表达,刺激后3小时,Fos表达达最高峰,而且主要在边缘区部位表达。正常大鼠纹状体边缘区中有密集的NOS阳性神经元及纤维,面部伤害性刺激3小时后,纹状体其余部位的NOS阳性胞体及纤维减少或消失,但边缘区中仍保留,并可见少数Fos和NOS双标记细胞,提示纹状体边缘区可能和面部痛觉的调制有关。     

树脑β－内啡肽能神经元胞体和纤维分布的研究

本文用免疫组织化学方法和免疫电镜方法对１４只树脑β－内啡肽能神经元胞体和纤维的分布及其在细胞器的定位进行了研究。结果表明，本文首次报道在Ｂｒｏｃａ斜角带观察到β－内啡肽免疫反应阳性神经元胞体，电镜观察到β－内啡肽免疫反应物质定位于大颗粒囊泡内的小颗粒上和粗面内质网上。下丘脑弓状核及其附近区域观察到β－内啡肽免疫反应阳性神经元胞体。在室周区、室旁核、第３脑室室管膜下层及室管膜上皮细胞间、内侧基底下丘脑及其外侧区、正中隆起内带和外带部可见到β－内啡肽免疫反应阳性纤维和串珠状的膨体。对β－内啡肽的释放途径及其调节因素作了探讨。     

AMPA受体与谷氨酸在大鼠三叉神经尾侧亚核内分布的免疫组织化学研究

本文用免疫组织化学ＡＢＣ法调查了４种ＡＭＰＡ受体亚单位（ＧｌｕＲ１、２／３、４）和谷氨酸（Ｇｌｕ）在大鼠三叉神经尾侧亚核（Ｖｃ）内的分布及其匹配关系。我们发现,ＧｌｕＲ１和２／３免疫阳性胞体和纤维密集分布于Ｖｃ的Ⅱ层和Ⅲ层外侧部,在Ｖｃ的其余各层呈散在性分布。ＧｌｕＲ４免疫阳性胞体和纤维在Ｖｃ各层均无分布。Ｇｌｕ免疫阳性胞体分布于Ｖｃ各层,尤以浅层（Ⅰ、Ⅱ层）密集,Ｇｌｕ免疫阳性纤维及终末结构主要分布于Ｖｃ浅层。结果表明,Ｇｌｕ免疫阳性纤维及终末样结构与ＡＭＰＡ受体免疫阳性胞体和纤维在Ｖｃ浅层的分布总体上是相互匹配的,但ＡＭＰＡ受体各亚单位在Ｖｃ内的分布存在明显的差异。本文提示,Ｖｃ内的Ｇｌｕ可能通过作用于不同的ＡＭＰＡ受体亚单位而发挥其多种生理功能     

神经激肽B受体在小鼠消化道内的定位

采用免疫组织化学ABC染色方法研究了神经激肽B受体（NK3r)在小鼠消化道的分布。MK3r样阳性的神经无胞体及神经纤维主要分布在十二指肠,空肠,回肠及结肠的粘膜下层神经丛和肌间神经丛,NK3r样阳性产物在食管,胃和直肠的神经丛中未见分布;NK3r样阳性产物大部分避限于神经细胞表面,也存在于胞和一些轴突内部,并在胞质中较细胞表面染色浅。。统计结果表明NK3r样免疫阳性神经元占肠神经系统神经元总数的0．5－1％,提示小鼠消化道内NK3r样阳性神经元可能参与消化功能的调节。     

河北环毛蚓神经系统 一氧化氮合酶的组织化学定位

用依赖还原型辅酶Ⅱ的黄酶组织化学方法,研究了环节动物门寡毛纲种类河北环毛蚓（Pheretima tschiliensis)神经系统k 一氧化氮合酶(NOS)阳性细胞及阳性纤维的分布,结果表明,河北环毛蚓神经系统中脑神经节背侧有大量细胞呈现NO强阳性反应,胞体和突起染色明显。咽下神经中偶尔能见少数染色较浅的神经元。在脑神经节腹内侧、围咽神经、 咽下神经节外侧部及腹神经链中都有一氧化氮合酶阳性纤维存在脸染色很深,实验结果表明,在环节动物中作为信息分子的一氧化氮已广泛存在于神经系统中。     

大熊猫胃肠道内分泌细胞分布型的研究

本文用ＰＡＰ法对３只大熊猫胃底,幽门腺区、十二脂肠,空肠,回肠、结肠和直肠的五羟色胺,生长抑素,胃素,胆囊收缩囊,神经降压素、胃动素、抑胃多肽、胰高血糖素、血管活性肠肽和内啡肽的ＩＲ细胞进行了研究。结果表明,大熊猫胃肠道粘膜上皮中具有前八种ＩＲ细胞。对７年龄个体胃肠各段相对数量的比较和各段内分布情况的观察结果表明,除五羟色胺ＩＲ细胞在空肠分布较多外,大多数种类的ＩＲ细胞集中分布于幽门区和十二指肠,     

发现有四种肽类物质共存于豚鼠小肠粘膜下神经元

通常认为胃肠道粘膜下神经节可能是感受胃肠粘膜刺激的感觉神经元或支配胃肠粘膜的运动神经元或兼而有之。近年来应用免疫组织化学染色技术发现:豚鼠小肠粘膜下神经节的神经细胞中含有多种脑肠肽以及合成乙酰胆碱所必需的酶的免疫反应活性,例如胆囊收缩素(CCK)、神经肽Y(NPY)、生长抑素(SOM),P物质(SP)、血管活性肠肽(VIP)、胆碱乙酰基转移酶(ChAT)的免疫活性。Furness等用相互间无交叉反应的高度特异性抗体同时标记豚鼠小肠粘膜下神经元中的不同抗原,再以荧光标记的高度特异性第二抗体标记第一抗体,研究了该神经胞体内各标记神经化学物质的共存情况。发现豚鼠小肠粘膜下神经节中神经元可分二大类:45%神经胞体中仅有VIP免疫反应性,主要集中在神经节中心,其神经末梢可能     

Immunohistochemical localization of some endocrine cells in the gastroenteropancreatic system of Erinaceus europaeus

The distribution of chromogranin A and neuron specific enolase (NSE) in the neuroendocrine gut system and the morphology and distribution of cells containing gastrin, somatostatin, neurotensin and VIP in the gastroenteropacreatic (GEP) apparatus of Erinaceus europaeus were investigated by immunohistochemical methods. Chromogranin A and somatostatin immunoreactive cells were present throughout the gastrointestinal mucosa, with the exception of the oesophagus and in the pancreas. Gastrin cells were peculiar of the pyloric glands and duodenal mucosa and neurotensin cells of the small intestine. No VIP immunoreactive endocrine cells were noticed in the GEP system. VIP and NSE immunoreactivities were detected both in nerve cell bodies and terminals of the wall of the GEP apparatus. NSE immunoreactivity was found in the endocrine cells of the fundic and pyloric mucosa.     

Ultrastructural study of neurotensin immunoreactivity in the superficial laminae of the dorsal horn of the rat

Neurotensin immunoreactivity was identified in cell bodies, dendrites, spines, axons, terminals and varicosities in superficial laminae of rat spinal cord with the electron microscope. Unlabeled terminals synapsed with neurotensin-immunoreactive cell bodies, dendrites and spines. Presynaptic terminals contained round or pleomorphic vesicles and generally made symmetrical contacts with medium-sized neurotensin-containing dendrites in outer lamina II, and asymmetrical or symmetrical contacts with large and small dendrites and spines in inner lamina II. Neurotensin immunoreactive axons were unmyelinated, and their terminals were presynaptic to unlabeled dendrites and spines in laminae I and II. Terminals contained small, round, clear vesciles (31 nm) and occasional large granular vesicles (78 nm). Contacts in outer lamina II were evenly distributed among dendrites of various sizes and spines, whereas the majority of labeled terminals in inner lamina II made contacts onto small dendrites and spines. These findings indicate that neurotensin effects in rat spinal cord are mediated by axodendritic synapses, and that neurotensin cells at the inner and outer borders of lamina II contact dendrites of efferent neurons or other interneurons in the dorsal horn.     

大鼠纹状体边缘区与Meynert氏基底核的突触联系及其与学习记忆功能的关系——WGA-HRP束路追踪法、电镜法和行为实验法研究

纹状体边缘区（ＭｒＤ）是我们先后在大鼠、猫和猴脑内新发现的一个区域。它是位于纹状体尾内侧、环绕着苍白球头外侧的一层梭形细胞。ＭｒＤ的细胞构筑、免疫组化特性和纤维联系形式不同于纹状体其它区。ＭｒＤ的离心投射终止在苍白球尾侧,接近Ｍｅｙｎｅｒｔ基底核（ＮＢＭ）附近。损毁双侧ＭｒＤ后,动物的学习记忆功能减弱。ＮＢＭ已知与动物智能有关。本研究用纤维溃变和束路追踪电镜法结合行为实验方法,旨在了解ＭｒＤ与ＮＢＭ之间有无突触联系,以及此种联系与动物学习记忆的关系。用纤维溃变和束路追踪电镜法研究表明,由ＭｒＤ发出的纤维终末与ＮＢＭ的胆碱能神经元胞体间存在着突触联系。损伤ＭｒＤ造成ＭｒＤ和ＮＢＭ形成突触联系的终末溃变后,动物的学习记忆能力降低。研究结果表明边缘区与Ｍｅｙｎｅｒｔ基底核间存在着突触联系,而这种联系很可能是ＭｒＤ的学习记忆功能的结构基础之一。     

Immunohistochemical detection of ganglia in the rat stomach serosa, containing neurons immunoreactive for gastrin-releasing peptide and vasoactive intestinal peptide

Ganglia, not previously described, were identified in the rat stomach serosa along the minor curvature. The ganglia consisted of varying number of cell bodies lying in clusters along or within nerve bundles. The ganglia were shown to contain GRP and VIP immunoreactive nerve fibers and cell bodies and also some NPY immunoreactive fibers, whereas they were devoid of somatostatin immunoreactivity. Nerve ligation experiments indicated that the ganglia are intrinsic to the stomach.     

Immunohistochemical detection of ganglia in the rat stomach serosa,containing neurons immunoreactive for gastrin-releasing peptide and vasoactive intestinal peptide

Summary Ganglia, not previously described, were identified in the rat stomach serosa along the minor curvature. The ganglia consisted of varying number of cell bodies lying in clusters along or within nerve bundles. The ganglia were shown to contain GRP and VIP immunoreactive nerve fibers and cell bodies and also some NPY immunoreactive fibers, whereas they were devoid of somatostatin immunoreactivity. Nerve ligation experiments indicated that the ganglia are intrinsic to the stomach.     

Synaptology of three peptidergic neuron types in the central nucleus of the rat amygdala

The synaptology of neurotensin (NT)-, somatostatin (SS)- and vasoactive intestinal polypeptide (VIP)-immunoreactive neurons was studied in the central nucleus of the rat amygdala (CNA). Three types of axon terminals formed synaptic contacts with peptide-immunoreactive neurons in the CNA: Type A terminals containing many round or oval vesicles; Type B terminals containing many pleomorphic vesicles; and Type C terminals containing fewer, pleomorphic vesicles. Peptide-immunoreactive terminals were type A. All three types of terminals formed symmetrical axosomatic and asymmetrical axodendritic contacts. However, type B and peptide-immunoreactive terminals frequently formed symmetrical axodendritic synaptic contacts. VIP-immunoreactive terminals also formed asymmetrical axodendritic contacts. SS- and NT-immunoreactive terminals commonly formed symmetrical contacts on SS- and NT-immunoreactive cell bodies, respectively. VIP-immunoreactive axon terminals were postsynaptic to nonreactive terminals. Type B terminals appeared more frequently on VIP neurons than on NT or SS neurons.