成年贵州小型猪淋巴结组织形态学观察及免疫组化研究

目的对成年贵州小型猪淋巴结进行形态学观察及免疫组化研究,为其用于建立人类免疫相关疾病模型提供参考。方法分别取24只成年贵州小型猪淋巴结组织进行固定、切片、HE染色,光镜下观察组织形态,免疫组化SP法检测CD3、CD4、CD8及CD20阳性细胞的比例和分布。结果成年贵州小型猪淋巴结皮质、髓质分布不规则,皮质、髓质并非完全倒置。皮质由淋巴小结和弥散性淋巴组织构成,髓质内可见髓索和髓窦。CD3、CD4、CD8阳性细胞主要分布在副皮质区,CD20阳性细胞主要分布在淋巴小结和髓质内。结论成年贵州小型猪淋巴结组织结构与其他哺乳动物有所不同,淋巴结内可见皮质、髓质倒置分布,但并非完全倒置。淋巴结中T、B细胞分布与人和其它哺乳动物之间没有明显的差异。     

豚鼠胸腺含P物质、降钙素基因相关肽和神经肽Y神经的定位研究

为研究神经肽调节胸腺生理功能的作用途径,作者采用免疫组织化学ＡＢＣ法结合ＧＤＮ增强技术,以３０μｍ厚恒冷箱切片光镜下观察了豚鼠胸腺内含ＳＰ、ＣＧＲＰ和ＮＰＹ神经纤维的定位与分布。结果发现,ＳＰ和ＣＧＲＰ免疫反应神经纤维在胸腺内分布广泛,呈线状或串珠状,可见于血管周围,小叶间结缔组织和胸腺实质。实质中以皮髓质交界区和髓质区纤维分布较密集,而走行于皮质淋巴组织的神经纤维相对稀疏,胸腺小体附近亦可见含ＣＧＲＰ神经分布。含ＮＰＹ神经纤维主要分布于血管周围、小叶间隔和皮髓质交界区,仅少数分支穿行于皮质胸腺细胞之间。胸腺被膜中有上述３种肽能神经纤维分布。本研究结果表明,胸腺内有丰富的肽能神经分布,这可能是神经肽调节胸腺生理功能的重要方式之一。     

人体胸腺和周围淋巴器官内T细胞亚群和NK细胞分布的研究

本文用多种Ｔ细胞和ＮＫ细胞单抗和免疫组织化学的ＡＢＣ技术,在冰冻切片上对人扁桃体、淋巴结、牌和胸腺内Ｔ细胞亚群和ＮＫ细胞的分布进行了检测。结果显示,ＣＤ５、ＣＤ８、ＣＤ４、ＣＤ３和ＡＩＧ３阳性细胞主要分布在扁桃体,淋巴结的副皮质区、脾的动脉周围淋巴鞘和胸腺,但各种抗体的反应强度不同。从各种Ｔ细胞工群的染色强度和形状看,胸腺髓质部的胸腺细胞相当于周围淋巴器官内的胸腺依赖区。胸腺内Ｔ细胞在分化过程中,质膜上的抗原也有相应变化。ＮＫ细胞主要分布在淋巴小结的生发中心,淋巴结和扁桃体的副皮质区,脾的红髓以及胸腺的筋质部。这些不同的分布,说明ＮＫ细胞不仅与淋巴小结的活动有关,可能还参与机体的免疫调节功能。     

环境无机汞对泥鳅视网膜S100表达影响

用含低浓度Hg2 的水饲养泥鳅(Misgurnus anguillicaudatus),研究Hg2 污染对视网膜中S100免疫反应阳性结构数量及分布的影响。用免疫组织化学ABC法标记S100免疫阳性(S100-IR)细胞,显微镜下观察S100免疫反应阳性细胞并计数。结果显示,处理组S100首先在神经节细胞层(GCL)、神经纤维层(NFL)表达,然后逐渐在其他各层表达。与对照组相比,处理组S100免疫反应阳性细胞数显著增多,且该变化与环境中无机汞处理时间成正相关;阳性细胞胞体明显膨胀,突起稠密粗大,S100阳性反应强。研究提示,Hg2 的神经毒害作用导致泥鳅视网膜中S100-IR细胞数的增多。推测Hg2 污染可能对视网膜有伤害性影响,而神经胶质细胞在视网膜修复过程中起了重要作用。     

淋巴结内FasL蛋白及其mRNA的表达

ＦａｓＬｉｇａｎｄ（ＦａｓＬ）与Ｆａｓ结合诱导细胞凋亡。这一机制对机体免疫反应可能起调节作用。运用ＦａｓＬ多克隆抗体、人工合成ＦａｓＬ寡核苷酸探针分别对淋巴结内ＦａｓＬ蛋白及ｍＲＮＡ进行免疫组织化学检测和原位杂交。结果：正常大鼠淋巴结副皮质区散在分布ＦａｓＬ阳性细胞;非特异性反应性增生的淋巴结内有大量ＦａｓＬ阳性细胞,主要分布在副皮质区,同时输出淋巴管内可见ＦａｓＬ阳性细胞。这为Ｆａｓ系统在参与淋巴细胞凋亡,以维持机体免疫平衡方面的作用提供了证据,同时也提示Ｆａｓ系统可能与某些感染性疾病的发病有关。     

人肠系膜淋巴结内树突细胞免疫细胞化学研究

本文用免疫细胞化学的方法检测了胎儿（胎龄２７～３８周）和成人肠系膜淋巴结内树突细胞的分布及对Ｓ－１００蛋白抗体和ＨＬＡ－ＤＲ抗体的反应。结果显示胎儿淋巴结内Ｓ－１００蛋白阳性树突细胞分布在外周区,中央区较少;这些细胞对ＨＬＡ－ＤＲ抗体亦呈阳性反应。成人淋巴结的树突细胞有两种,一种是位于初级和次级淋巴小结生发中心的小结树突细胞,另一种是位于小结间和副皮质区的交错突细胞。小结树突细胞与ＨＬＡ－ＤＲ抗体呈阴性反应,而交错突细胞则呈强阳性,提示这两种细胞不仅在分布上不同,而且对ＨＬＡ－ＤＲ抗体反应也不同。进一步证实了小结树突细胞和交错实细胞在细胞来源和免疫功能方面是不同的两种辅助性细胞。     

S100在猫小脑中的分布及其表达的年龄相关性变化

用免疫组织化学ABC法标记S100免疫阳性(S100-IR)细胞,观察S100蛋白在青年猫和老年猫小脑中的分布,探讨其表达的年龄相关变化及意义。光镜下计数颗粒层和髓质中S100-IR细胞密度及浦肯野细胞(PC)层阳性细胞线密度。结果显示,颗粒层和髓质中S100-IR细胞密度较小、分布均匀,PC层阳性细胞相对密集,分子层未见阳性反应;阳性细胞胞浆深染。与青年猫相比,老年猫小脑颗粒层、髓质和PC层中S100-IR细胞密度显著增加(P<0.01),胞体较大,阳性较强。表明S100-IR细胞在小脑中的分布具区域性差异,呈明显的年龄相关性增生,推测其增生对衰老神经元的丢失起保护作用。     

大鼠胃、胰CGRP阳性细胞的免疫组织化学观察

用免疫组织化学ABC法观察了大鼠胃,胰CGRP的分布。结果显示;（1）在大鼠胃内有大量的CGRP阳性神经纤维存在。未见CGRP阳性神经元。（2）大鼠胃窦部可见到少量CGRP阳性细胞：（3）在大鼠胰岛内有两种CGRP阳性内分泌细胞存在。     

猴脾脏内NPY、CGRP、SP 和 VIP免疫反应神经纤维的分布

本文应用 ABC 免疫组织化学染色法结合葡萄糖氧化酶-DAB-硫酸镍铵(GDN)显色技术,观察了神经肽 Y(NPY)降钙素基因相关肽(CGRP)、P 物质(SP)和血管活性肠肽(VIP)免疫反应(Immunoreactire,IR)阳性神经纤维在猴脾脏的分布。结果发现,NPY-IR 神经纤维沿脾的动脉、静脉及其分支走行,在被膜、小梁、白髓、红髓和边缘区亦有分布。CGRP-IR 和SP-IR 神经纤维在脾脏的分布相同,主要沿脾动脉走行,中央动脉周围尤为丰富,白髓和红髓的淋巴组织中有少许分布。VIP-IR 神经纤维主要分布在中央动脉周围,白髓和边缘区有零星分布。猴脾脏肽能神经纤维末梢与免疫细胞接触密切,揭示它们对免疫细胞的发育和活性具有调节作用。本研究为神经免疫调节机制提供了形态学依据。     

大鼠脑内血管的单胺能神经分布——免疫组织化学法研究

本实验应用ABC免疫过氧化物酶法,以酪氨酸羟化酶(TH)作为标记物,观察了10只Wistar大鼠脑实质内血管的中枢去甲肾上腺素能神经分布。脑实质内血管壁明显可见免疫反应阳性去甲肾上腺素能神经纤维。对端脑皮质、海马、下丘脑、脑桥、延髓各部位血管的神经形态进行了描述。皮质血管的阳性纤维数量较多,纤维较细,相互交织成网,膨体可见;髓质内血管的阳性纤维较稀,似线样结构。讨论了中枢去甲肾上腺素能神经对脑实质内血管以及局部脑循环的作用。     

Neuron-specific enolase,neurofilament protein and S-100 protein in the olfactory mucosa of human fetuses

Summary Immunohistochemical examination for neuronspecific enolase (NSE), neurofilament protein (NFP), and S-100 protein was performed in the olfactory mucosa of human fetuses. NSE and NFP immunoreactivities were found in the olfactory receptor cells, while no S-100 immunoreactive cells were recognized within the olfactory epithelium. The anti-NSE serum stained various types of nerve bundles in the lamina propria mucosae; a population of the NSE-positive nerve bundles was also immunoreactive for NFP. The anti-S-100 serum clearly demonstrated Schwann cells associated with the nerve fibers in the lamina propria mucosae. These findings 1) suggest a possibility of NSE and NFP as new marker substances for olfactory cells and 2) indicate that immunohistochemistry is a useful tool to analyse the cellular components of the olfactory organs in normal and pathological conditions.     

Distribution and ultrastructure of S-100-immunoreactive cells in the human thymus

Summary The present study deals with the localization and ultrastructure of S-100-immunoreactive cells in the human thymus. These immunoreactive cells are distributed mainly in the medulla with some scattered elements in the cortex. Electron-microscopic observation revealed that the cells are characterized by an irregularly shaped nucleus, tubulovesicular structures in the cytoplasm and characteristic interdigitations of the plasma membrane. The cells often embrace lymphocytes with their branched processes. On the basis of these morphological features, the immunostained elements were identified as interdigitating cells (IDCs). The immunocytochemistry for S-100 visualizes the precise distribution and extension of the IDCs under the light microscope and indicates that the IDCs form no structural networks such as those established by the thymic epithelial cells. Since the IDCs in human lymph nodes have also been reported to contain S-100-like immunoreactivity, S-100 protein can be regarded as a useful marker for identifying the IDCs in the human thymus and other lymphoid organs.     

Further evidence for the T-cell nature of the atypical mononuclear cells in mycosis fungoides

It is well known that in some cases of mycosis fungoides the lymph nodes contain atypical mononuclear cells with a characteristic electron-microscopic morphology, first described in skin lesions of mycosis fungoides. Because it has been shown, that these cells have T-cell membrane characteristics the question can be raised, if these cells have other properties of T cells. One of these is a preferential localization in the T-cell dependent regions (paracortical areas) of the lymph node. In this paper we present a study of dermatopathic lymph nodes from four patients with mycosis fungoides (plaque stage). The lymph nodes of these patients contained atypical mono nuclear cells in the paracortical areas only, and not in the follicles or medulla. In one of the patients we could demonstrate the migration of these cells through the epitheloid venules into the paracortical area.     

Quantitative comparison of growth-associated protein GAP-43, neuron-specific enolase, and protein gene product 9.5 as neuronal markers in mature human intestine.

This study was performed to compare GAP-43, PGP 9.5, synaptophysin, and NSE as neuronal markers in the human intestine. GAP-43-immunoreactive nerve fibers were abundant in all layers of the ileum and colon. GAP-43 partially co-localized partially with every neuropeptide (VIP, substance P, galanin, enkephalin) studied. All neuropeptide-immunoreactive fibers also showed GAP-43 reactivity. By blind visual estimation, the numbers of GAP-43-immunoreactive fibers in the lamina propria were greater than those of PGP 9.5, synaptophysin, or NSE. In the muscle layer, visual estimation indicated that the density of GAP-43-immunoreactive fiber profiles was slightly greater than that of the others. The number and intensity of GAP-43-, PGP 9.5-, and NSE-immunoreactive fibers were estimated in sections of normal human colon and ileum using computerized morphometry. In the colon, the numbers of GAP-43-immunoreactive nerve profiles per unit area and their size and intensity were significantly greater than the values for PGP and NSE. A similar trend was observed in the ileum. Neuronal somata lacked or showed only weak GAP-43 immunoreactivity, variable PGP 9.5 immunoreactivity, no synaptophysin immunoreactivity, and moderate to strong NSE immunoreactivity. We conclude that GAP-43 is the superior marker of nerve fibers in the human intestine, whereas NSE is the marker of choice for neuronal somata. (J Histochem Cytochem 47:1405-1415, 1999)     

Different distribution of S-100 protein and glial fibrillary acidic protein (GFAP) immunoreactive cells and their relations with nitrergic neurons in the human fetal small intestine.

The appearance, distribution and some histochemical features of non-neuronal cells (NN cells) associated with the myenteric plexus of human fetal small intestine have been studied by means of S-100 protein and GFAP immunocytochemistry between the 10th and 17th week of gestation. In addition, double labelling immunocytochemistry using an antibody raised against a constitutive isoform of nitric oxide synthase (bNOS) in combination with an S-100 protein antibody was applied to investigate the morphological relations between NN cells and nitrergic neurons in the developing gut wall. Cells with immunoreactivity for both glial-specific proteins are already present in the 10th week of gestation. While cells with S-100 protein immunoreactivity are located within the circular muscle layer as well as in the myenteric, and submucous plexuses, cells with GFAP immunopositivity are mainly restricted to the side of the myenteric plexus adjacent to the longitudinal muscle layer. In contrast to the dense network formed by S-100 protein immunopositive structures the GFAP immunopositive cells appear singly and do not connect into a network. Double-labelling immunocytochemistry reveals nitrergic fibers (NOS-IR) in close relation to the S-100 protein immunoreactive glial network. NOS-IR varicosities are in close association with the surface of those cells both in the circular muscle layer (CM) and in the tertiary plexus. It is concluded that two populations of NN cells with different locations and different immunohistochemical characters appear and develop together with the enteric ganglia in the human fetal intestine. The close morphological relation of NOS-IR fibers with S-100 protein immunopositive cellular network indicate a functional relationship between S-100 protein immunopositive cells and the nitrergic nerves during the early development of human enteric nervous system (ENS).     

Distribution of five peptides, three general neuroendocrine markers, and two synaptic-vesicle-associated proteins in the spinal cord and dorsal root ganglia of the adult and newborn dog: an immunocytochemical study

This study describes the immunocytochemical distribution of five neuropeptides (calcitonin gene-related peptide [CGRP], enkephalin, galanin, somatostatin, and substance P), three neuronal markers (neurofilament triplet proteins, neuron-specific enolase [NSE], and protein gene product 9.5), and two synaptic-vesicle-associated proteins (synapsin I and synaptophysin) in the spinal cord and dorsal root ganglia of adult and newborn dogs. CGRP and substance P were the only peptides detectable at birth in the spinal cord; they were present within a small number of immunoreactive fibers concentrated in laminae I-II. CGRP immunoreactivity was also observed in motoneurons and in dorsal root ganglion cells. In adult animals, all peptides under study were localized to varicose fibers forming rich plexuses within laminae I-III and, to a lesser extent, lamina X and the intermediolateral cell columns. Some dorsal root ganglion neurons were CGRP- and/or substance P-immunoreactive. The other antigens were present in the spinal cord and dorsal root ganglia of both adult and newborn animals, with the exception of NSE, which, at birth, was not detectable in spinal cord neurons. Moreover, synapsin I/synaptophysin immunoreactivity, at birth, was restricted to laminae I-II, while in adult dogs, immunostaining was observed in terminal-like elements throughout the spinal neuropil. These results suggest that in the dog spinal cord and dorsal root ganglia, peptide-containing pathways complete their development during postnatal life, together with the full expression of NSE and synapsin I/synaptophysin immunoreactivities. In adulthood, peptide distribution is similar to that described in other mammals, although a relative absence of immunoreactive cell bodies was observed in the spinal cord.     

High endothelial venules of the lymph nodes express Fas ligand.

Fas (CD95, APO-1) is widely expressed on lymphatic cells, and by interacting with its natural ligand (Fas-L), Fas induces apoptosis through a complex caspase cascade. In this study we sought to survey Fas-L expression in vascular and sinusoidal structures of human reactive lymph nodes. Immunohistochemical Fas-L expression was present in all paracortical high endothelial venules (HEVs), in cells lining the marginal sinus wall, and in a few lymphocytes, but only occasionally in non-HEV vascular endothelium. In the paracortical zone over 60% of all vessels and all paracortical HEVs showed Fas-L expression, whereas in the medullary zone less than 10% of the blood vessels were stained with Fas-L. Normal vessels outside lymph nodes mostly showed no Fas-L expression. We show that in human reactive lymph nodes Fas-L expression is predominantly present in HEVs. Because the circulating lymphocytes gain entry to nodal parenchyma by transendothelial migration through HEVs, the suggested physiological importance of Fas-L expression in these vessels lies in the regulation of lymphocyte access to lymph node parenchyma by possibly inducing Fas/Fas-L mediated apoptosis of activated Fas-expressing lymphoid cells. The Fas-L expressing cells in the marginal sinus might have a similar function for cells accessing the node in afferent lymph.     

Enhanced replication of simian immunodeficiency virus adjacent to catecholaminergic varicosities in primate lymph nodes

Clinical and in vitro studies have shown that activity of the autonomic nervous system (ANS) can stimulate lentivirus replication. To define the potential anatomical basis for this effect, we analyzed the spatial relationship between catecholaminergic neural fibers and sites of simian immunodeficiency virus (SIV) replication in lymph nodes from rhesus macaques experimentally infected with SIVmac251. Viral replication was mapped by in situ hybridization for SIV env, gag, and nef RNA, and catecholaminergic varicosities from the ANS were mapped by sucrose phosphate glyoxylic acid chemofluorescence. Spatial statistical analyses showed that the likelihood of active SIV replication increased by 3.9-fold in the vicinity of catecholaminergic varicosities (P < 0.0001). The densities of both ANS innervation and SIV replication differed across cortical, paracortical, and medullary regions of the lymph node, but analyses of each region separately continued to show increased replication of SIV adjacent to catecholaminergic varicosities. Ancillary analyses ruled out the possibility that SIV-induced alterations in lymph node architecture might create a spurious spatial association. These data support human clinical studies and in vitro molecular analyses showing that catecholamine neurotransmitters from the ANS can increase lentiviral replication by identifying a specific anatomic context for interactions between ANS neural fibers and replication of SIV in lymphoid tissue.     

Immunohistochemical studies of neurochemical markers in normal human buccal mucosa

The content of various substances, such as regulatory peptides, hormones and structural proteins, was investigated in normal buccal mucosa using indirect immunofluorescence. Thin nerve fibres, which from a morphological point of view were most probably sensory, showed immunoreactivity for substance P (SP), calcitonin gene-related peptide (CGRP), neuropeptide K (NPK) and neurokinin A (NKA). Also galanin (GAL), -melanocyte stimulating hormone (-MSH) and somatostatin (SOM) stained thin fibres were found in the propria, which were, however, few in number and the -MSH staining was weak. CGRP, vasoactive intestinal polypeptide (VIP), peptide histidine isoleucine amide (PHI) and neuropeptide Y (NPY) immunoreactive nerve fibres were observed in close connection to blood vessels. SOM positive cells with processes were found, mostly scattered, in the connective tissue. A population of cells within the epithelium also showed somatostatin immunoreactivity. Protein S-100 (S-100) stained distinct populations of cells at two separate locations. In the propria, cells with one or two slender processes were seen, being mostly single but sometimes forming groups. In the epithelium, dendritic cells with many processes with or without spines were observed, mainly located to the basal layer of the lamina epithelialis. Single nerve fibres and nerve bundles were also stained. Neurofilament (NF) positive fibres, singly and in bundles, as well as endorgan-like structures were seen. Neuron-specific enolase (NSE) and protein gene product 9.5 (PGP 9.5) both stained the same structures, namely single fibres, nerve bundles, nerves surrounding vessels and innervating muscles and glands (if present in the section), as well as Merkel cells. Also with these two markers endorgan-like structures were seen. No clear innervation of the epithelium could be observed with the markers used. No methionine-enkephalin (ENK) or synaptophysin (SYN) immunoreactive material was found.     

Differentiation of Langerhans Cells from Interdigitating Cells Using CD1a and S-100 Protein Antibodies

The present study shows that Langerhans cells can be differentiated from Interdigitating cells at the light microscopic level. Superficial lymph nodes and skin taken from necropsies and the lymph nodes of dermatopathic lymphadenopathy (DPL) were used for this experiment. Sections of lymph node and skin were embedded using the acetone, methyl benzoate and xylene (AMeX) method and dendritic cells were immunostained with anti S-100 protein antibody (S-100, and OKT-6 (CD1a) using the restaining method. Langerhans cells in the skin were positive for both CD1a and S-100. Dendritic cells positive for both CD1a and S-100, and dendritic cells positive for S-100, but not for CD1a were observed in superficial lymph nodes. In normal superficial lymph nodes, there were more interdigitating cells than Langerhans cells. The majority of the dendritic cells in the DPL were Langerhans cells. We conclude that the S-100 and CD1a positive cells are Langerhans cells, and the S-100 positive-CD1a negative cells are interdigitating cells.