新生大鼠雌激素注射后睾丸肥大细胞的变化

新生大鼠注射雌二醇后,睾丸肥大细胞于第30天可见到,细胞数量随年龄增长而增多,生后4－6个月,睾丸网附近仍可见大量肥大细胞。睾丸内的肥大细胞比皮肤内的结缔组织肥大细胞（CTMC）小而与小肠粘膜的粘膜肥大细胞（MMC）相近,AB－S染色后基本着蓝色,硫酸小檗碱荧光染色后呈现中等强度黄色荧光,结果提示,新生大鼠雌激素注射后睾丸内肥大细胞的增多可能与免疫过程有关,睾丸内肥大细胞与CTMC和MMC皆有所不同。     

多重PAP及多重PAP结合ABC免疫细胞化学方法的建立、敏感性分析与应用

作者在传统的 PAP 及 ABC 染色方法的基础上,通过重复使用桥抗及 PAP 的次数或重复使用生物素化桥抗及 PAP 和 ABC 的次数,使 PAP 与 ABC 方法成功地结合,增加连接于抗原部位的酶分子数,建立起两种敏感的免疫细胞化学方法。染色结果经显微分光光度图象分析,方差分析,回归分析及染色效果的直接观察表明,重复染色可增加阳性强度,扩大阳性染色范围,提高信噪比,从而提高方法的敏感性,以生物素化桥抗取代非生物素化桥抗,将 ABC 引入到多重 PAP 方法中,可使方法的敏感性进一步提高。该方法结合单克隆抗体及多克隆抗体成功地检测出用传统双PAP 及 ABC 难以或不能检测出的常规福尔马林固定石蜡包埋的肾综合征出血热尸检组织中的病毒抗原及石蜡包埋肿瘤活检组织中的桥粒抗原。     

肥大细胞的组织化学与超微结构异质性

肥大细胞(mast cell,MC)是一种重要的免疫细胞,分为结缔组织肥大细胞(connective tissue mast cell,CTMC)和黏膜肥大细胞(mucosal mast cell,MMC)两大类。肥大细胞具有异质性,即肥大细胞在不同种属或同一种种属的不同个体、甚至同一种个体的不同组织器官中存在着形态学、分布、颗粒化学成分、染色特性及超微结构和功能等方面的差异性。近些年,人们围绕着肥大细胞的异质性进行了一系列生物学研究,并取得了一定进展,但对异质性的机制认识尚不清楚。深入的讨论、研究与比较仍然很必要。现对肥大细胞的亚群、形态与分布、着染性与免疫组化、超微结构等的异质性研究进展作一简要综述。     

从甲状腺肥大细胞探讨胎儿器官肥大细胞的差异

研究肥大细胞在人胎儿甲状腺发育中数量、分布及组化性质的改变,以探讨胎儿器官发育中肥大细胞的差异。取45例不同胎龄的人胎甲状腺石蜡切片做甲苯胺蓝染色和阿尔辛蓝－－藏红染色,并测定肥大细胞的临界电解质浓度值及进行硫酸小蘖硷荧光染色。结果显示：3月龄胎儿甲状腺内开始出现肥大细胞,数量极少,主要分布在被膜及小叶间结缔组织内,甲苯胺蓝染色肥大细胞颗粒呈淡紫蓝色,阿尔辛蓝－－藏红染色呈蓝色,临界电解质浓度值较低,硫酸小蘖硷染色未见显黄色荧乐的肥大细胞,从3月龄到足月随着胎龄增长,肥大细胞数量缓慢增多,8月龄时肥大细胞经甲苯胺蓝染色,其颗粒呈紫红色,阿尔辛蓝－－藏红染色出现少量含红色和红蓝混合染色颗粒的肥大细胞,临界电解质浓度值偏高,可见少量显黄色荧光的肥大细胞,结果表明：在人胎儿3月龄时甲状腺发育中开始出现肥大细胞,但随胎儿发育肥大细胞的组化性质改变不明显。     

应用不同固定及染色方法确定商城肥鲵肥大细胞的分布

为了解商城肥鲵(Pachyhynobius shangchengensis)肥大细胞(mast cell,MC)的分布和形态特点,丰富有尾两栖类MC的生物学资料,用不同固定和染色方法对商城肥鲵消化系统及其他部分器官的肥大细胞进行了观察,并对消化道和舌的MC数量进行统计.结果表明,除输卵管和肾外,在3种固定方法中,改良甲...     

虎纹蛙消化道肥大细胞类胰蛋白酶免疫组化研究

研究采用小鼠抗人肥大细胞类胰蛋白酶单克隆抗体AA1,应用ElivisionTM plus免疫组化染色法对虎纹蛙(Rana tigrina rugulosa)消化道组织中类胰蛋白酶阳性肥大细胞存在的可能性进行研究。研究发现单克隆抗体AAl可与中性缓冲福马林液固定的虎纹蛙组织的肥大细胞获得良好的交叉反应,类胰蛋白酶阳性细胞胞浆染成棕黄色,证实虎纹蛙肥大细胞胞浆颗粒中也存在类胰蛋白酶。虎纹蛙组织中AA1免疫染色阳性细胞的分布,与AB/SO和改良甲苯胺兰染色阳性细胞的分布存在较大的差异:虎纹蛙类胰蛋白酶阳性细胞数量很少,且阳性反应比人胃癌间质肥大细胞弱,主要见于黏膜型肥大细胞(MMC)分布区域,如消化道黏膜上皮下方和固有层,少量分布于肠绒毛基底部及食管腺和胃腺周围。而在结缔组织型肥大细胞(CTMC)分布区域,如消化道黏膜下层结缔组织中却未见类胰蛋白酶阳性细胞。AB/SO和改良甲苯胺兰染色阳性细胞数量多,广泛分布于消化道黏膜固有层、黏膜下层、腺体之间、肌间及外膜结缔组织,说明并不是所有的虎纹蛙肥大细胞都含有类胰蛋白酶。很有可能是虎纹蛙MMC中含有类胰蛋白酶,而CTMC中不含类胰蛋白酶。虎纹蛙类胰蛋白酶阳性细胞数量很少,且阳性反应比人胃癌间质肥大细胞弱,说明虎纹蛙肥大细胞胞浆颗粒类胰蛋白酶含量较少,虎纹蛙属于低等脊椎动物,可能与生物进化水平较低有关,有待进一步研究。       

免疫酶双重染色中抗体洗脱的进一步研究

本实验进一步检查了三种常用的洗脱方法从切片上除去免疫酶组织化学染色后的抗体的效果。结果表明,PAP法染色后,氧化法的抗体洗脱完全,效果可靠;酸洗法和酸洗/二甲基甲酰胺法的效果视不同抗体而不同,二甲基甲酰胺单用或用于酸洗后似无效。所用方法均不能从ABC法染色的垂体组织切片上完全除去抗体复合物。因之,将ABC法用于第一抗体来源于同一动物种的双重染色中,来显示第一种抗原时,要特别注意排除假性双标记。     

发育中人胎儿肥大细胞的组织化学研究

用组织化学技术,对５０例不同胎龄胎儿颊部和食管肥大细胞进行了研究。我们发现：幼稚的肥大细胞颗粒ＴＢ染色呈淡紫色。ＡＢ·Ｓ染色呈蓝色,ＣＥＣ值偏低,颗粒的糖胺多糖硫酸化程度偏低;成熟的肥大细胞颗粒ＴＢ染色呈深紫色,ＡＢ·Ｓ染色呈红色,ＣＥＣ值偏高,颗粒的糖胺多硫酸化程度偏高,含肝素。颊部、食管的肥大细胞在出现的时间、ＡＢ·Ｓ组化染色、ＣＥＣ值与肝素含量等存在不同。结果说明发育中胎儿肥大细胞颗粒的组化性质发生了改变,不同部位肥大细胞的发育是不同步的,这些是发育中胎儿肥大细胞异质性的表现。本文对这些现象进行了讨论。     

胡子鲶粘液细胞类型及其在消化道中的分布

利用阿新兰过碘酸雪夫试剂染色方法 ,对胡子鲶粘液细胞类型以及在消化道中的分布进行了研究。根据AB PAS染色结果 ,将粘液细胞分为四型 :Ⅰ型 ,AB PAS染色呈红色 ,含有PAS阳性的中性粘多糖 ;Ⅱ型 ,AB PAS染色呈蓝色 ,含有AB阳性的酸性粘多糖 ;Ⅲ型 ,AB PAS染色呈紫红色 ,主要含有PAS阳性的中性粘多糖 ,同时含有少量AB阳性的酸性粘多糖 ;Ⅳ型 ,AB PAS染色呈蓝紫色 ,主要含有AB阳性的酸性粘多糖 ,同时含有少量PAS阳性的中性粘多糖。同时发现粘液细胞在消化道的各段均有分布 ,但是不同部位的粘液细胞数和类型均有差异。     

大鼠睾丸组织固定法的优选研究

目的选择一种最优势、合理的固定方式以提高对睾丸组织制片效果,以配合不同种类的科学研究。方法选用10％甲醛溶液、NBF—Bouin’s、Bouin’s和改良Davidson’s四种不同的固定液对大鼠睾丸进行充分固定后,制作石蜡切片,进行HE染色,比较不同固定液中的睾丸组织学形态的差异;利用糖原特殊染色（PAS）,探讨不同固定液对睾丸糖原观察的影响;采用免疫组织化染色,测评睾丸组织内雄激素受体的固定效果。结果改良Davidson’8固定液较NBF—Bouin’s引起的曲细精管萎缩轻,形态更为清晰,用免疫组织化学方法检测雄激素更为敏感,并且改良Davidson＇s固定液在需要对精子发生进行分期时,其PAS染色的效果与Bouin＇s液固定后等同。结论与苴守圈常浦相№曲冉David0Rnn浦对女宙奥由的圈索特罩掂杯     

Stochastic model for mast cell proliferation in culture of murine peritoneal cells

We recently identified two types of mast cell colonies derived from murine peritoneal cells: type 1 and type 2. Type 1 mast cell colonies consisted of berberine sulfate(+)- safranin(+) connective tissue-type mast cells (CTMC) and were derived from mature CTMC in the heaviest fraction obtained by Percoll density gradient centrifugation. In contrast, type 2 mast cell colonies consisted of alcian blue(+)- berberine sulfate(-)- safranin(-) mucosal mast cells (MMC) and were derived from immature progenitors in low density fractions. We replated a total of 60 type 1 and 60 type 2 mast cell colonies and examined their capability for producing secondary colonies. Although all of the primary colonies yielded secondary colonies, the replating efficiencies of individual colonies varied over a wide range. Cumulative distributions of secondary colonies from both type 1 and type 2 primary colonies could be fitted well by gamma distributions obtained by computer simulation. These findings are in agreement with the stochastic model for CTMC- and MMC proliferation. Cytological analyses of secondary colonies from primary type 1 colonies revealed heterogeneous distributions of alcian blue(+)- safranin(-)- berberine sulfate(-) mast cells, suggesting that transdifferentiation from mature CTMC to safranin(-)- berberine sulfate(-) mast cells is also governed by stochastic mechanisms.     

Establishment and characterization of hybrid rat mast cells

Rat peritoneal mast cells (RPMC) and rat basophilic leukemia (RBL) cells are representative of connective tissue-type (CTMC) and mucosal-type (MMC) mast cells, respectively. Using polyethylene glycol, we have fused RPMC with 6-thioguanine resistant, HAT (hypoxanthine, aminopterin, thymidine) sensitive RBL-CA10.7 or RBL-CK2 cells, yielding several hybrid rat mast cell lines (HRMC). The hybridomas exhibited different size and cytoplasmic granularity when compared with parental cell lines. Analysis of both high (Fc epsilon RI) and low affinity (Fc epsilon RL) receptors for IgE revealed that the hybrid lines had more variable receptor patterns than the parent lines. Three hybridoma lines were chosen for further study. Differential histochemical staining with alcian blue and safranin O dyes indicated the hybrids to be predominantly of the MMC type: however, a few cells of one of these uncloned hybridomas were found to be of the CTMC type. Attempts to isolate the CTMC hybridomas yielded one culture which was predominantly of the CTMC phenotype and in a number of other cultures, cells were found expressing simultaneously both the CTMC and the MMC phenotype. After 3 weeks in culture, however, all hybridomas, including those which were cloned further, expressed only the MMC histochemical phenotype. This was found to correlate with the presence of rat mast cell protease II (RMCPII) and the absence of RMCPI in all hybridomas, as detected by Western blot analysis. In addition, the histamine content of all cells was significantly lower than that of the parent RPMC. Most hybrid mast cells expressed both Fc epsilon RI and Fc epsilon RL which in some cases exhibited significant variations in the Mr. These results indicate that somatic cell hybrids expressing the MMC and CTMC phenotype can be produced by the fusion of RBL and RPMC. The CTMC phenotype, however, is unstable, and possible reasons for this are discussed.     

Restoration of hepatic mast cells and expression of a different mast cell protease phenotype in regenerating rat liver after 70%-hepatectomy

Mast cells (MC) can undergo significant changes in number and phenotype; these alterations result in the differential expression of growth factors and cytokines. Kit ligand (KL; stem cell factor) is produced by mesenchymal cells, and in the liver by biliary epithelial cells. Recent studies suggest that KL, and its receptor c-kit, may be involved in liver regeneration after loss of liver mass. However, KL is also the major growth, differentiating, chemotactic, and activating factor for MC. The aim of our study was to elucidate the dynamics and phenotype of hepatic MC and KL/c-kit expression during liver regeneration after partial (70%) hepatectomy in the rat. Regenerating livers were harvested after 1, 3, 7, and 14 days, respectively (n = 6 each day). MC were stained for naphthol-AS/D-chloroacetate esterase and counted as MC per bile ductule. MC phenotype was assessed by rat MC protease (RMCP)-1 and -2 immunofluorescence staining, in order to distinguish RMCP-1 positive connective tissue MC (CTMC) from RMCP-2 positive mucosa MC (MMC). mRNA expression of RMCP, c-kit, and the differentially spliced variants of KL was quantified by RT-PCR. MC counts per bile ductule decreased in regenerating rat liver tissue at day 3, compared with native livers, and became normal thereafter. Hepatic MC were predominantly of a CTMC phenotype expressing RMCP-1, as previously published; after hepatectomy, between 76 and 99% of all MC double-expressed RMCP-1 and -2, compatible with an MMC phenotype. The ratio of the two alternatively spliced mRNAs for KL (KL-1 : KL-2), and c-kit mRNA expression did not differ significantly between regenerating livers and the livers of sham operated animals. These results suggest that hepatic mast cells are restored during liver regeneration after partial hepatectomy in the rat. Restored MC express an MMC phenotype, suggesting migration from outside into the regenerating liver. Alternative splicing of KL is affected by the surgical procedure in general, and, together with its receptor c-kit, doesn't seem to be involved in liver regeneration after partial hepatectomy in the rat. Further functional studies, and studies in regenerating human livers might offer the possibility of elucidating the role of the hepatic mast cell, and its different protease phenotypes during liver regeneration after surgical loss of liver mass.     

间接免疫过氧化物酶技术鉴定猪和牛的肥大细胞

用小鼠抗人肥大细胞类胰蛋白酶单克隆抗体ＡＡ１,ＡＡ３及ＡＡ５的间接免疫过氧化物酶技术对经Ｃａｒｎｏｙ液或中性缓冲福尔马林固定的猪和犊牛空肠,舌及胸腺的石蜡切片进行了免疫染色。对猪和牛的肥大细胞特异性免疫染色与常规的组织化学染色的结果进行了比较。     

Hepatic mast cells in rats infected with Taenia taeniaeformis

Mast cells appeared in the liver around metacestodes of Taenia taeniaeformis by 13 days after infection (DAI) of rats. The cells often occurred in clusters. The population increased until 28 DAI, then gradually declined. These hepatic mast cells (HMC) were compared to intestinal mucosal mast cells (MMC) and connective tissue mast cells (CTMC) histochemically, morphologically and in their response in vivo to Compound (built|48/80) and dexamethasone. Hepatic mast cells were similar to MMC in that they stained strongly blue with Astra blue at pH 1·0, could not be demonstrated with 0·005% toluidine blue, disappeared after treatment with dexamethasone, and were unaffected by 48/80. Immunoglobulin-containing cells in the liver were characterized by immunofluorescence. Immunoglobulin E-positive, and to a lesser extent IgG_2a-, and IgG_2c-positive cells surround the parasites in increasing numbers until 28 DAI, then declined. Many IgE-positive cells were HMC, and the IgE was frequently located intracytoplasmically. These cells were clearly distinguishable from eosinophils which stained characteristically with Giemsa and did not react with the anti-IgE probe. The results suggest that mast cell progenitors may be induced to localize and proliferate at the host-parasite interface in the Taenia-infected livers, giving rise to a cell population comparable to the MMC often seen at parasitized mucosal surfaces.     

Development of mucosal mast cells after injection of a single connective tissue-type mast cell in the stomach mucosa of genetically mast cell-deficient W/Wv mice

Mast cells may be classified into at least two phenotypically distinct populations: connective tissue-type mast cells (CTMC) and mucosal mast cells (MMC). Mast cells in the peritoneal cavity of mice are typical CTMC, whereas mast cells in the mucosa of the stomach show morphologic characteristics of MMC. We investigated whether CTMC may change to MMC. A single peritoneal mast cell of WBB6F1-+/+ mice was identified under the phase-contrast microscope, picked up with the micromanipulator, and injected into the stomach wall of genetically mast cell-deficient WBB6F1-W/Wv mice. The cells with histochemical and electron microscopical features of MMC developed in the mucosa, and those with histochemical features of CTMC in the muscularis propria. This directly demonstrates that a certain proportion of CTMC may function as a bipotent precursor for both MMC and CTMC.     

Histochemical heterogeneity of dermal mast cells in athymic and normal rats

Summary Mucosal mast cells (MMC) and connective tissue mast cells (CTMC) of the rat contain different proteoglycans, which can be distinguished using histochemical methods. The chondroitin sulphate proteoglycan of the MMC, unlike the heparin of the CTMC, does not show fluorescent berberine binding, is susceptible to aldehyde fixatives and stains preferentially with Alcian Blue in a staining sequence with Safranin. The majority of the dermal mast cells are typical CTMC and are located in the deep part of the dermis. Subepidermal mast cells are comparatively few in normal rats but numerous in athymic rats and mice. These cells differ from other dermal mast cells in that they stain preferentially with Alcian Blue and they appear to contain little histamine. We examined some of the histochemical properties of the skin mast cells of female PVG-rnu/rnu rats and their heterozygous littermates aged from 5 to 29 weeks. The thiazine dye-binding of the subepidermal mast cells was partially blocked by formaldehyde fixation and only about half of them showed a weakly fluorescent berberine binding. The critical electrolyte concentration of the Alcian Blue staining of the subepidermal mast cells was between that of CTMC and MMC. Deaminative cleavage with nitrous acid abolished the staining of all skin mast cells, while that of the MMC was unaffected. There were no statistically significant differences in the staining patterns of the dermal mast cells between different ages or groups of rat. These results indicate that the subepidermal mast cells contain a heparin proteoglycan which is, however, different from that of the typical CTMC of other sites. They thus appear to represent a second example of a mast cell within a defined anatomical location exhibiting a distinct proteoglycan expression.     

A new technique for staining mast cells using ferroin

We describe here a new method for specific staining of mast cells using ferroin. Different hamster tissues were fixed in 4% formalin and processed for paraffin embedding. Sections were stained with hematoxylin followed by ferroin acidified with 2.5 N sulfuric acid to pH 4.0. Mast cells stained an intense orange color that contrasted markedly with bluish violet nuclei. High contrast was also observed when ferroin colored sections were counterstained with light green instead of hematoxylin. To evaluate the specificity of the stain, hamster cheek pouch sections were stained with toluidine blue, alcian blue-safranin O, and ferroin. Quantitative evaluation of mast cells stained with the three techniques showed no statistical difference. The simplicity and selectivity of this method is sufficient for image analysis of mast cells.     

A new technique for staining mast cells using ferroin

We describe here a new method for specific staining of mast cells using ferroin. Different hamster tissues were fixed in 4% formalin and processed for paraffin embedding. Sections were stained with hematoxylin followed by ferroin acidified with 2.5 N sulfuric acid to pH 4.0. Mast cells stained an intense orange color that contrasted markedly with bluish violet nuclei. High contrast was also observed when ferroin colored sections were counterstained with light green instead of hematoxylin. To evaluate the specificity of the stain, hamster cheek pouch sections were stained with toluidine blue, alcian blue-safranin O, and ferroin. Quantitative evaluation of mast cells stained with the three techniques showed no statistical difference. The simplicity and selectivity of this method is sufficient for image analysis of mast cells.