An antibody raised against in vitro-derived human mast cells identifies mature mast cells and a population of cells that are Fc epsilon RI(+), tryptase(-), and chymase(-) in a variety of human tissues.

Selective markers for human mast cells are of paramount importance for understanding their role in physiological and pathological processes. A mouse monoclonal antibody (MAb) designated 2C7, raised against in vitro-derived human mast cells, was used in immunoenzymatic analysis of sections from a variety of human organs. Double immunolabeling with 2C7 and tryptase, chymase, Fc epsilon RIalpha, and c-kit was performed on cryostat tissue sections from skin, colon, uterus, breast, stomach, bladder, and lung. MAb 2C7 stained greater than 93% of the tryptase(+) or chymase(+) mast cells in all tissues examined. In addition, the majority of cells stained with the tryptase or chymase also stained for Fc epsilon RIalpha. However, there were a significant number of Fc epsilon RIalpha(1) cells in all tissues studied that were tryptase(-) and/or chymase(-). In contrast, MAb 2C7 in double immunoenzymatic staining co-localized with 93-96% of the Fc epsilon RIalpha(1) cells in all tissues. Analysis for c-kit expression on the different tissues revealed that the majority of tryptase(+) or chymase(+) cells in skin, uterus, bladder, and lung stained with c-kit. However, only approximately 70-78% of tryptase(+) cells in colon and stomach were c-kit(+). These data suggest that MAb 2C7 appears to identify mature mast cells and a population of Fc epsilon RIalpha(1), chymase(-), and tryptase(-) cells in a variety of human tissues.     

The immunohistochemical demonstration of chymase and tryptase in human intestinal mast cells

Summary An immunohistochemical double-labelling technique for the simultaneous identification of mast cells containing tryptase alone (MC_T) or chymase together with tryptase (MC_TC) was evaluated quantitatively using two monoclonal antibodies, mAb 1222A (antitryptase) and mAb 1254B (antichymase). Saturation conditions were established for the binding of the antibodies to the mast cell enzymes by counting labelled mast cells in consecutive sections of normal human intestine incubated with serial dilutions of the antibodies. When, under such conditions, the antitryptase was applied after saturation with mAb 1254B, the reproducibility of the double-labelling procedure was excellent. MC_T were located preferentially in the intestinal mucosa but, in contrast to what has previously been reported, they were not the predominant type of mast cell at this site. The percentage of MC_T of the total number of immunopositive mast cells varied considerably in the colonic mucosa (7–67%, average 30%), while this was not the case in the small intestinal mucosa (5–26%, average 10%). Mast cell chymase, unlike tryptase, was not recognized by the antichymase antibody after aldehyde fixation and a higher apparent fraction of MC_T therefore occurred after double labelling. These findings suggest that the proteinase composition of human mast cells, unlike that of murine mast cells, should not be taken as evidence of phenotypic heterogeneity. Taken together with previous observations, they suggest instead that the lack of chymase may be related to functional activity or stage of maturation of the mast cells.     

Detection of MCT and MCTC types of human mast cells by immunohistochemistry using new monoclonal anti-tryptase and anti-chymase antibodies

We developed an improved immunohistochemical technique for distinguishing human mast cells of the MCT (tryptase-positive, chymase-negative) and MCTC (tryptase-positive, chymase-positive) types utilizing a biotinylated murine anti-chymase monoclonal antibody (MAb), termed B7, and an alkaline phosphatase-conjugated murine anti-tryptase MAb, termed G3. The B7 MAb also was used to show the selective presence of chymase in mast cells. The distribution of MCT and MCTC cells in Carnoy's fluid-fixed tissue sections of human lung, skin, small intestine, and tonsils was analyzed by the new technique and the results compared to those obtained with the older method using a rabbit polyclonal antichymase antibody and a mouse anti-tryptase MAb in indirect immunoperoxidase and indirect immunoalkaline phosphatase protocols, respectively. In tissues known to contain predominantly mature mast cells, there were no quantitative differences between the two techniques, although the staining intensity achieved with the anti-chymase MAb was greater and without development of high background, compared to results achieved with the polyclonal antibody. MCT cells were the predominant type seen in the alveoli of the lung (93%) and in the small intestinal mucosa (81%). MCTC cells predominanted in the skin (99%) and in the small intestinal submucosa (77%) and, to a lesser degree, in tonsils (60%). However, in newborn foreskin tissue which contains predominantly immature forms of mast cells, 75% of all mast cells were stained uniformly and intensely with B7, whereas only 43% were stained with the polyclonal anti-chymase antibody. Therefore, the use of MAb provides for better standardization of reagents and more accurate assessment of the distribution of human MCT and MCTC cells in tissues than previously available methods.     

Mast cell heterogeneity in the human uvea

To identify chymase- and tryptase-positive mast cells in the human uvea, and to study their associations with different types of resident uveal cells, uveal specimens from 24 human donor eyes were cryosectioned in sagittal and tangential planes. Enzyme histochemical staining of chymase was combined with immunohistochemical staining for tryptase, detected with the APAAP method. Fluorescence immunohistochemistry was performed with antibodies against c-kit, alpha smooth muscle actin, protein gene product (PGP) 9.5, CD45, and HLA-DR. In different uveal compartments, the total amounts of mast cells were calculated and the distributions of chymase and tryptase were quantified. All uveal mast cells were c-kit and CD45 positive and HLA-DR negative. No association existed between mast cells and actin-containing cells. Only a few mast cells were in close association with PGP 9.5-labeled nerve fibers. In the choroid, most mast cells were located in the inner central part (mean density = 48.9/mm²), and contained both chymase and tryptase (96%). The ciliary muscle contained numerous mast cells (mean density = 33.7/mm²), many of them tryptase positive but chymase negative (63%). In the pars plana, a high number of chymase-positive, tryptase-negative mast cells were found (20%). In the iris only a few mast cells were present. Although the choroid contains the most common subtype of mast cells, a unique situation concerning the distribution of chymase and tryptase is present in the anterior uveal tissues. A possible role for these cells in the special immunological situation of the anterior eye chamber merits further investigation. Accepted: 16 September 1999     

Human mast cell carboxypeptidase. Selective localization to MCTC cells

Two murine mAb were prepared against human mast cell carboxypeptidase (HMC-CP) purified from human skin, and were termed CP1 and CP2, respectively. Double immunohistochemical labeling of Carnoy's-fixed sections of human skin, lung, and gastrointestinal tissue with CP1 and CP2, respectively, and with a murine monoclonal antitryptase antibody demonstrated that HMC-CP was selectively present in a subset of human mast cells. Double labeling experiments with CP1 and CP2, respectively, and a murine anti-chymase mAb demonstrated the presence of HMC-CP in the tryptase-positive, chymase-positive mast cell type (MCTC) only. Immunohistochemical labeling of peripheral blood leukocytes resulted in staining of monocytes with CP2 but not with CP1. In addition to chymase and a cathepsin-G like proteinase, HMC-CP is another neutral protease that is selectively present in the MCTC tryptase-positive, chymase-positive mast cells type of mast cell, thus extending the biochemical definition of human mast cell heterogeneity.     

Chymase and tryptase in dog mastocytoma cells: asynchronous expression as revealed by enzyme cytochemical staining

Mast cell populations can be distinguished by differences in the content and substrate specificity of their two major cytoplasmic granule proteases, the chymases and the tryptases. To explore the origins of differences in the types of proteases present in mast cells, we used a double cytochemical staining technique to reveal both chymase and tryptase in cells from four lines of dog mast cell tumors containing both enzymes. We expected that if chymase and tryptase were expressed together during cell development the relative staining intensity of chymase compared to tryptase would be constant among different cells of each tumor. Instead, we found substantial variation in the relative intensity of chymase and tryptase staining among cells of a given mastocytoma line, each of which contained cells presumed to be monoclonal in origin but heterogeneous with respect to cell development. The overall staining intensity for chymase or tryptase correlated with the amount of protease activity in extracts of tumor homogenates. Staining specificity was established by use of selective inhibitors and competitive substrates and was tested on various types of dog cells obtained by bronchoalveolar lavage. The results suggest that active chymase and tryptase may be expressed differently during mast cell differentiation and support the possibility of a close developmental relationship between mast cells differing in protease phenotype. Moreover, the success of the staining procedures applied to mastocytoma cells suggests that they may be of general utility in phenotyping of mast cells according to the protease activities present in their granules.     

Identification of a cathepsin G-like proteinase in the MCTC type of human mast cell

Human mast cells can be divided into two subsets based on serine proteinase composition: a subset that contains the serine proteinases tryptase and chymase (MCTC), and a subset that contains only tryptase (MCT). In this study we examined both types of mast cells for two additional proteinases, cathepsin G and elastase, which are the major serine proteinases of neutrophils. Because human mast cell chymase and cathepsin G are both chymotrypsin-like proteinases, the properties of these enzymes were further defined to confirm their distinctiveness. Comparison of their N-terminal sequences showed 30% nonidentity over the first 35 amino acids, and comparison of their amino acid compositions demonstrated a marked difference in their Arg/Lys ratios, which was approximately 1 for chymase and 10 for cathepsin G. Endoglycosidase F treatment increased the electrophoretic mobility of chymase on SDS gels, indicating significant N-linked carbohydrate on chymase; no effect was observed on cathepsin G. Immunoprecipitation and immunoblotting with specific antisera to each proteinase revealed little, if any, detectable cross-reactivity. Immunocytochemical studies showed selective labelling of MCTC type mast cells by cathepsin G antiserum in sections of human skin, lung, and bowel. No labeling of mast cells by elastase antiserum was detected in the same tissues, or in dispersed mast cells from lung and skin. A protein cross-reactive with cathepsin G was identified in extracts of human skin mast cells by immunoblot analysis. This protein had a slightly higher Mr (30,000) than the predominant form of neutrophil cathepsin G (Mr 28,000), and could not be separated from chymase (Mr 30,000) by SDS gel electrophoresis because of the size similarity. Using casein, a protein substrate hydrolyzed at comparable rates by chymase and cathepsin G, it was shown that about 30% of the caseinolytic activity in mast cell extracts was sensitive to inhibitors of cathepsin G that had no effect on chymase. Hydrolytic activity characteristic of elastase was not detected in these extracts. These studies indicate that human MCTC mast cells may contain two different chymotrypsin-like proteinases: chymase and a proteinase more closely related to cathepsin G, both of which are undetectable in MCT mast cells. Neutrophil elastase, on the other hand, was not detected in human mast cells by our procedures.     

Chymotrypsin- and trypsin-type serine proteases in rat mast cells: properties and functions

Two of the major enzymes present in and released from rat mast cells are chymotrypsin-type serine protease (chymase) and trypsin-type serine protease (tryptase), and these have been postulated to be important in the inflammatory reactions. There have been no clear data regarding the trypsin-type protease in rat mast cells. Tryptase was recently purified from rat peritoneal mast cells with an associated protein (trypstatin) that inhibited the protease activity above pH 7.5. Chymase was also purified from rat peritoneal cells by employing a one-step method involving hydrophobic chromatography on octyl-Sepharose 4B or arginine-Sepharose 4B. The properties of chymase and tryptase were described in relation to substrate specificity and their relative sensitivity to inhibitors. It was found that proteolytic activities of these enzymes were modulated by naturally occurring substances, such as phosphoglycerides, long-chain fatty acids, and trypstatin. There is as yet little evidence for the physiological roles of these enzymes in the inflammatory reaction. It has been found that the specific, low-molecular-weight inhibitor of chymase, chymostatin, and that of tryptase, leupeptin, inhibit histamine release induced by addition of anti-rat IgE to mast cells. However, the inhibitors with molecular weights of more than 6000 were found to have no effect in this process. The data suggest that chymase and tryptase in mast cell granules play a crucial or significant role in the process of degranulation.     

Detection and partial characterization of a human mast cell carboxypeptidase

Using a high performance liquid chromatography assay that detects the cleavage of the C-terminal leucine from angiotensin I, we have identified a carboxypeptidase activity in mast cells from human lung and in dispersed mast cell preparations from human skin. The enzyme activity was detected in a preparation of dispersed human mast cells from lung of greater than 99% purity and was released with histamine after stimulation with goat anti-human IgE. In nine preparations of dispersed human mast cells from lung of 10 to 99% purity, net percentage of release of carboxypeptidase correlated with the release of histamine, localizing carboxypeptidase to mast cell secretory granules. The enzyme activity was also detected in preparations of dispersed human mast cells from skin and in extracts of whole skin. The inhibitor profile and m.w. of carboxypeptidase activity from preparations of dispersed mast cells from skin was similar to that from dispersed mast cells from lung. Mast cell carboxypeptidase had a m.w. on gel filtration of 30,000 to 35,000. The enzyme in crude lysates of dispersed mast cell preparations had optimal activity between pH 8.5 and 9.5 and was inhibited by potato inhibitor, which distinguished it from carboxypeptidase in cultured human foreskin keratinocytes and adult fibroblasts, and from other proteolytic mast cell enzymes. The enzyme activity was also inhibited by EDTA, o-phenanthroline, and, to a small extent, by 8-OH quinoline, but not by Captopril, soybean trypsin inhibitor, or pepstatin. These findings demonstrate that human mast cell secretory granules contain carboxypeptidase in addition to tryptase and chymase. It appears that mast cells from skin may have a higher content of carboxypeptidase than do mast cells from lung.     

Thymosin beta 4 expression in normal skin,colon mucosa and in tumor infiltrating mast cells

Mast cells (MCs) are metachromatic cells that originate from multipotential hemopoietic stem cells in the bone marrow. Two distinct populations of MCs have been characterized: mucosal MCs are tryptase-positive while mast cells in skin contain tryptase and chymase. We now show that a sub-population of MCs is highly immunoreactive for thymosin β₄, as revealed by immunohistochemical analyses of normal skin, normal colon mucosa and salivary gland tumors. Four consecutive serial sections from each case were immunostained for thymosin β₄ (Tβ₄), chymase, tryptase and stained for toluidine blue. In skin biopsies, MCs showed a comparable immunoreactivity for Tβ₄, chymase and tryptase. In normal colon mucosa the vast majority of mucosal MCs expressed a strong cytoplasmic immunoreactivity for tryptase and for Tβ₄, in the absence of chymase reactivity. A robust expression of Tβ₄ was detected in tumor-infiltrating and peritumoral mast cells in salivary gland tumors and breast ductal infiltrating carcinomas. Tumorinfiltrating MCs also showed a strong immunoreactivity for chymase and tryptase. In this paper, we first demonstrate that normal dermal and mucosal mast cells exhibit strong expression of thymosin β₄, which could be considered a new marker for the identification of mast cells in skin biopsies as well as in human tumors. The possible relationship between the degree of Tβ₄ expression in tumor-infiltrating mast cells and tumor behaviour warrants further consideration in future investigations.Key words: mast cells, thymosin β₄, tryptase, chymase.     

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。       

Evaluation of human peripheral blood leukocytes for mast cell tryptase

Murine monoclonal and goat polyclonal antibodies against tryptase, the dominant neutral protease and protein component in secretory granules of human mast cells, were used to assess the presence of tryptase in peripheral leukocytes. Carnoy's fluid-fixed cytocentrifuge preparations of enriched populations of lymphocytes, monocytes, eosinophils, and neutrophils showed no reactivity with anti-tryptase antibodies by a sensitive indirect immunoperoxidase procedure. Dispersed human lung mast cells showed strong granular cytoplasmic staining with both antibodies, whereas only approximately 50% of the peripheral blood basophils detectable with Wright's stain were detected with anti-tryptase antibodies, and these showed a staining pattern that was faint, granular, and cytoplasmic at high concentrations of antibody. At lower antibody concentrations mast cell staining was still intense, whereas basophils were not stained. Extracts of neutrophils and lymphocytes of up to 90% purity had undetectable amounts of tryptase by an ELISA sandwich immunoassay, as well as undetectable enzymatic activity with tosyl-L-gly-pro-lys-p-nitroanilide (a sensitive substrate for tryptase) in the presence of soybean trypsin inhibitor. Extracts of basophil-enriched (6 to 50% purity) preparations contained 0.046 +/- 0.013 pg of tryptase per basophil by the immunoassay along with 2 X 10(-9) +/- 0.8 X 10(-9) U of tryptase-like enzyme activity per basophil, compared with corresponding values of 12 pg, 480 X 10(-9) U of tryptase per human lung mast cell. Thus very small amounts of tryptase are present in human basophils (approximately 0.4% of that found in mast cells), but not in other peripheral leukocytes.     

Human mast cell chymase cleaves pro-IL-18 and generates a novel and biologically active IL-18 fragment

Increased release of IL-18 in the skin causes atopic dermatitis (AD)-like skin lesions, suggesting a role of IL-18 in the pathogenesis of AD. Caspase-1 is a well-known activator of IL-18, but caspase-1 knockout mice still have biologically active IL-18. Normal human keratinocyte constitutively produces pro-IL-18, but it is unable to activate it, suggesting the existence of an alternative pathway for IL-18 in the skin. Dermal accumulation of mast cells is commonly observed in AD patients and in experimental mouse models of AD. Connective tissue mast cells contain high amounts of chymase and tryptase in their cytoplasmic granules. In the present study, we demonstrated that activation of IL-18 is a novel function of human mast cell chymase. Human mast cell chymase rapidly cleaves recombinant pro-IL-18 at 56-phenylalanine and produces a biologically active IL-18 fragment that is smaller than any other reported IL-18-derived species. The human mast cell chymase and the novel IL-18-derived active peptide may be novel therapeutic targets in AD- and IL-18-associated diseases.     

Serum amyloid A (SAA) activates human mast cells which leads into degradation of SAA and generation of an amyloidogenic SAA fragment

Serum amyloid A (SAA) is a precursor for the amyloid A in AA type of amyloidosis. Distribution of mast cells in tissues is similar to the distribution of amyloid deposits in secondary AA-amyloidosis. Therefore, we studied whether mast cells could be involved in SAA metabolism. Human mast cell line (HMC-1) cells were cultured with recombinant human apoSAA (rhSAA), and the production of tumour necrosis factor (TNF)-alpha and interleukin (IL)-1 beta was determined by ELISA. RhSAA and human SAA (huSAA) were incubated with human chymase, tryptase or with intact human mast cell (huMC) in cultures, and degradation of SAA was followed by gel electrophoresis, liquid chromatography and mass spectrometry. SAA induced dose-dependent production of TNF-alpha and IL-1 beta in HMC-1 cells. Tryptase, chymase, and huMC granules degraded efficiently the SAA protein. Degradation of SAA by tryptase, but not by chymase, released a highly amyloidogenic N-terminal fragment of SAA. Finally, incubation of huMC with rhSAA alone resulted in degradation of SAA and formation of protofibrillar intermediates. These results suggest a pathogenic role for mast cells in AA-amyloidosis.     

Enzyme histochemical discrimination between tryptase and chymase in mast cells of human gut

We tested four synthetic substances for their histochemical value to demonstrate the catalytic activities of chymase or tryptase in mast cells in sections of human gut. Both Suc-Ala-Ala-Phe-4 methoxy-2-naphthylamide (MNA) and N-acetyl-L-methionine-alpha-naphthyl ester (alpha-N-O-Met) reacted with chymase but not tryptase in mast cells. Conversely, D-Val-Leu-Arg-MNA and Z-Ala-Ala-Lys-MNA were hydrolyzed by mast cell tryptase but not chymase. These results were confirmed by use of two inhibitors of chymotrypsin-like activity, chymostatin and Z-Gly-Leu-Phe-chloromethyl ketone (CK) and two inhibitors of trypsin-like activity, Tos-Lys-CK and D-Val-Leu-Arg-CK. Excellent staining reactions were obtained on cryostat sections of unfixed or aldehyde-fixed tissues and on paraffin sections of Carnoy-fixed tissues. For chymase, however, Suc-Ala-Ala-Phe-MNA is preferred on cryostat sections because it is more specific. On paraffin sections alpha-N-O-Met is preferred because other cells are not then stained. For tryptase, Z-Ala-Ala-Lys-MNA was more selective and more specific and is the preferred general purpose substrate on cryostat sections of aldehyde-fixed tissues and for paraffin sections. D-Val-Leu-Arg-MNA is the preferred substrate for cryostat sections of unfixed tissue. Only a limited number of mast cells showed a reaction for chymase, and these occurred mainly in the submucosa. All mast cells, however, gave a reaction for tryptase, and we recommend the use of either substrate for this enzyme for routine detection of mast cells in human tissues. Double staining for the two main mast cell proteases is most conveniently undertaken on paraffin sections of Carnoy-fixed tissues using MNA substrates for tryptase and alpha-N-O-Met for chymase.     

Monoclonal antibodies against human mast cell tryptase demonstrate shared antigenic sites on subunits of tryptase and selective localization of the enzyme to mast cells

Two murine monoclonal antibodies were prepared against tryptase, the major neutral protease and protein component of human mast cells. The antibodies were termed G5 (IgG2B-kappa) and H4 (IgG1-kappa). They were specific for tryptase by an enzyme-linked immunosorbent assay and an immunotransblot technique. The latter procedure showed that H4 and G5 each bind to the 35,000 and 37,000 m.w. subunits of tryptase, indicating immunologic cross-reactivity between the subunits. The monoclonal antibodies reacted only with tryptase subunits in an extract of dispersed lung cells. By immunofluorescence microscopy, tryptase was further identified to be present only in cytoplasmic granules of Alcian Blue-stained mast cells in dispersed pulmonary cell preparations. No evidence for a mast cell subtype lacking tryptase was detected. In addition, a procedure for the purification of tryptase to homogeneity from dispersed pulmonary cells containing less than 10% mast cells was developed; this procedure involved high salt extraction, ammonium sulfate precipitation, and sequential chromatography with decyl-agarose, DEAE-agarose, and heparin-agarose. The procedure resulted in a higher yield even with less pure starting material than reported previously. Tryptase is a selective marker for mast cells in dispersed pulmonary cells, and can be detected with specific anti-tryptase antibodies.     

Rat mast cell tryptase

Rat mast cell tryptase is located largely if not totally in the cell's secretory granules. When the active site reagent [3H]diisopropyl fluorophosphate was used to label tryptase and chymase simultaneously, the ratio of tryptase:chymase active sites was determined to be 0.05. In comparison to chymase and tryptase in other species and chymase in the rat, rat tryptase is poorly bound to the granule matrix as evidenced by (1) its release parallel to histamine on induction of secretion and (2) its appearance in the supernatant when isolated granules were stripped of their membranes with hypotonic medium. Tryptase on release from the granule is moderately stable at a pH of 5.0 but unstable at pH 7.5, the pH that the enzyme encounters on secretion from the cell. These several properties indicate that the role of rat mast cell tryptase extracellularly is likely to differ greatly from that of chymase.     

Tryptase and chymase are angiogenic in vivo in the chorioallantoic membrane assay

Human mast cells (MCs) are divided in two types depending on the expression of tryptase and chymase in their granules. Literature data indicate that both tryptase and chymase are angiogenic, but there is currently no evidence of their direct angiogenic activity in vivo. In this study, we have investigated the capacity of tryptase and chymase to promote vasoproliferation in chick embryo chorioallantoic membrane (CAM), a well established in vivo assay to study angiogenesis and anti-angiogenesis. The results showed that both tryptase and chymase stimulate angiogenesis and that the response is similar to that obtained with vascular endothelial growth factor (VEGF), a well-known angiogenic cytokine, and confirm the angiogenic activity of these two proteases stored in MC granules.     

用免疫荧光标记对人组织中肥大细胞亚型的分选与形态观察

方法:利用中性蛋白酶成分、特征性酶抗体的免疫荧光染色和流式细胞仪确定分选肥大细胞亚型,以激光扫描共聚焦显微镜显示肥大细胞内分泌颗粒。结果:三种免疫表型被确定:肥大细胞的类胰蛋白酶阳性(MCT)、类糜蛋白酶阴性;类糜蛋白酶阳性(MCC)、类胰蛋白酶阴性和类胰蛋白酶阳性、类糜蛋白酶阳性(MCTC)。肥大细胞内分泌颗粒分散或聚集存在,分泌颗粒突起分泌或以分散的方式释放。分泌颗粒大范围释放后,肥大细胞的形态结构发生了改变。结论:利用肥大细胞的特征性酶抗体、免疫荧光标记和流式细胞仪可将人组织中的肥大细胞分选纯化为三种亚型;以共聚焦显微镜显示肥大细胞含有丰富的分泌颗粒,它说明肥大细胞具备了为人体I型变态反应提供快速反应的物质基础。     

Mast cells in human bile duct obstruction

Surgical biopsy specimens obtained from 50 patients with secondary cholangitis caused by obstruction of the common bile duct were studied immunohistochemically. Data on the number and ultrastructural appearances of mast cells positive for tryptase, chymase, vasointestinal polypeptide (VIP), and substance P (SP) were obtained. The bile ducts from patients presenting combined chronic exacerbated cholangitis and chronic sclerotic cholangitis showed significantly higher numbers of mast cell types compared to the controls (P < 0.0001). Cases with sclerotic cholangitis alone had significantly lower number of cells than patients with chronic exacerbated cholangitis alone (P 0.0001). Morphometric measurements of electron micrographs showed that mast cell granules containing VIP, SP and chymase were commensurable in size. Electron-lucent granules without reaction product (altered granules) and granules with focal distribution of the reaction product were observed in all types of mast cells. Furthermore, some nerve fibers positive for SP and VIP and serotonin-positive endocrine cells were observed in close proximity to the mast cells. In conclusion, the results of our study demonstrate the existence of different populations of mast cells, nerve structures and endocrine cells in the lower part of the human large bile duct, and suggest their participation in the development of pathological processes.