Chromatin fluorescence after carmine staining

After staining with dilute solutions (0.1 mg/ml in distilled water) of commercial carmine, a strong reddish orange fluorescence was observed in nuclei from cell smears and frozen and paraffin tissue sections. Optimal exciting light was 436 nm (violet-blue) or 450-490 nm (blue). Compact chromatin from interphase nuclei, mitotic and meiotic chromosomes and the kinetoplast of Trypanosoma cruzi showed the highest fluorescence, while the basophilic cytoplasm appeared weakly fluorescent. No emission was observed in cartilage matrix, mast cell granules or goblet cell mucin. This selective method could be valuable in microscopic and cytochemical studies on chromatin because the carmine fluorescence is stable and preparations can be dehydrated and mounted permanently without changes in the fluorescence pattern.     

Chromatin Fluorescence after Carmine Staining

After staining with dilute solutions (0.1 mg/ml in distilled water) of commercial carmine, a strong reddish orange fluorescence was observed in nuclei from cell smears and frozen and paraffin tissue sections. Optimal exciting light ws 436 nm (violet-blue) or 450-490 nm (blue). Compact chromatin from interphase nuclei, mitotic and meiotic chromosomes and the kinetoplast of Trypanosoma cruzi showed the highest fluorescence, while the basophilic cytoplasm appeared weakly fluorescent. No emission was observed in cartilage matrix, mast cell granules or goblet cell mucin. This selective method could be valuable in microscopic and cytochemical studies on chromatin because the carmine fluorescence is stable and preparations can be dehydrated and mounted permanently without changes in the fluorescence pattern.     

Enzyme histochemistry of rat mast cell tryptase

Fixation and staining conditions for rat mast cell tryptase and its histochemical distribution in different rat tissues were investigated. Prostate, skin, lung, gut, stomach and salivary glands were fixed in either aldehyde or Carnoy fixatives and then frozen or embedded in paraffin wax. Preservation of tryptase enzymic activity against peptide substrates required aldehyde fixation and frozen sectioning. Of the peptide substrates examined, z-Ala-Ala-Lys-4-methoxy-2-naphthylamide and z-Gly-Pro-Arg-4-methoxy-2-naphthylamide proved the most effective for the demonstration of tryptase. Double staining by enzyme cytochemistry followed by immunological detection of tryptase showed that, in all tryptase-containing mast cells, the enzyme is at least in part active. Conventional dye-binding histochemistry was used to confirm the identity of mast cells. Aldehyde-fixed mucosal mast cells required a much shorter staining time with Toluidine Blue if tissue sections were washed directly in t-butyl alcohol. Double staining by enzyme cytochemistry and dye binding showed that tryptase is absent from mucosal and subepidermal mast cells, which are also smaller in size and appear to contain fewer granules than connective tissue mast cells. This study demonstrates that rat mast cell tryptase, unlike tryptases in other species, is a soluble enzyme. It is stored in an active form and is absent from some mast cell subpopulations in mucosa, skin and lung. © 1998 Chapman & Hall     

Selection of a simple protease procedure for identifying mast cells in routinely processed human tissues

Proteases present in mast cell granules have been harnessed to demonstrate mast cells in human tissues. A number of substrate mixtures were tested. D-Val-Leu-Arg-4-methoxy-2-naphthylamide (MNA) plus Fast Blue B was the best for identifying human mast cells, yielding the most specific and complete staining. The procedure is simple and the results are permanent. Cryostat sections of aldehyde-fixed routine preparations or paraffin sections of Carnoy-fixed tissues give the most satisfactory results. Mast cells are stained a strong red color that stands out distinctly from the surrounding tissues, so that they can be easily identified by simple microscopy. A double-staining technique, first for protease and subsequently using Alcian Blue, showed that as progressive protease staining occurs, the alcianophilia of mast cells is lost. This procedure demonstrated that mast cells in the mucosa of human gut generally required longer incubations to develop protease staining than in other connective tissue sites. In post-mortem tissues, mast cells retain their protease activity well and so can be demonstrated in cryostat sections of aldehyde-fixed material, giving a more complete picture than with Alcian Blue. The synthetic substrate D-Val-Leu-Arg-MNA can be recommended for routine identification of mast cells in human tissues.     

Beige granules as a cell marker for clonal analysis in kidney and liver of mouse aggregation chimaeras, and three-dimensional reconstruction from serial paraffin sections

Anomalous giant granules of beige (bg) mice have been used as a cell marker in the study of cell lineage of mast cells. Similar granules are known to exist in other tissues including kidney proximal tubules and liver parenchymal cells. In the present study, these granules were found to give yellow or orange autofluorescence when the tissue had been fixed with formaldehyde and embedded in paraffin. Thus, the granules can be used as a cell marker that can be visualized in serial paraffin sections without any specific histochemical staining. Chimaeric mice were produced by aggregation of 8-cell-stage embryos of beige (C57BL/6J-bgJ/bgJ) and A/J strains. The chimaeric liver showed beige cell patches with complicated shapes, although the patches frequently conformed to the shape of parenchymal cell cord or plate structures. In chimaeric kidney, beige cells formed coherent patches in the proximal tubules. The tubules were found to contain more than one clone. The patches frequently had long extended shapes suggesting growth of the clone along the tubule axis. Three-dimensional image reconstruction from the serial paraffin sections was carried out with the aid of a computer-assisted image analysis system, resulting in a clearer image of the patch shape.     

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.     

Mucosal mast cells of the rat intestine: a re-evaluation of fixation and staining properties, with special reference to protein blocking and solubility of the granular glycosaminoglycan

Mucosal mast cells of the gastrointestinal tract constitute a separate cell line within the mast cell system of the rat, differing in several respects from the classical connective tissue mast cells and, unlike the latter, requiring special fixation techniques for their demonstration. We have examined some histochemical properties of mucosal mast cells of the duodenum and compared them with connective tissue mast cells of the tongue or skin. The results indicate that the structural integrity of the granules of both types of mast cell is partly dependent on ionic linkages between glycosaminoglycan and protein. The so far unidentified glycosaminoglycan of mucosal mast cells appears to be more soluble than the heparin of connective tissue mast cells. The strongly fluorescent binding of Berberine to the granules of connective tissue mast cells and, depending on their content, of heparin is absent from mucosal mast cells, confirming previous findings which suggested that they contain a glycosaminoglycan with a lower degree of sulphation. Aldehyde fixation by routine procedures reversibly blocks the cationic dye binding of mucosal mast cell granules. The dye binding groups may be unmasked by trypsination or by long staining times of the order of several days. The results suggest that the blocking of staining by aldehydes is caused by a diffusion barrier of a protein nature. Mucosal and connective tissue mast cells thus differ with respect to the spatial arrangement of glycosaminoglycan and protein in their granules. As a result of the study a modified method for the demonstration of mucosal mast cells in tissue sections is described, based on normal formaldehyde fixation and staining in Toluidine Blue for a long time. It has some advantages over previous methods and preserves the structure of mucosal and connective tissue mast cells equally well.     

DIFFERENTIATION AND PROLIFERATION OF EMBRYONIC MAST CELLS OF THE RAT

Histochemical reactions and radioautography were used to investigate the sequence of mast cell development in rat embryos. Mast cells arise ubiquitously in and are confined to the loose connective tissue in the embryo. The alcian blue-safranin reaction distinguishes between weakly sulfated and strongly sulfated mucopolysaccharides by a shift from alcian blue to safranin staining. Based on this reaction and morphologic characteristics, four stages were identified. Stage I mast cells are lymphocyte-like cells with cytoplasmic granules which invariably stain blue with the alcian blue-safranin reaction. In Stage II cells the majority of granules are alcian blue-positive, but some safranin-positive granules have appeared. Stage III mast cells are distinguished by a majority of safranin-positive cytoplasmic granules; some alcian blue-positive granules still remain. Stage IV cells contain only safranin-positive granules. Thymidine-H³ uptake and identification of mitotic figures indicates that mast cells in Stages I and II comprise a mitotic pool while those in Stages III and IV are mitotically inactive. The pattern of S³⁵O₄ incorporation and the sequence of appearance of histochemically identifiable mast cell constituents corroborates division of the proliferation and differentiation of embryonic mast cells into the four stages described above. The process of formation of mast cell granules is interpreted as reflecting the synthesis and accumulation of a heparin precursor in alcian blue positive granules followed by the synthesis and accumulation of highly N-sulfated heparin along with mast cell chymase and finally histamine in safranin-positive granules.     

Morphological alteration of peritoneal mast cells and macrophages in the mouse peritoneal cavity during the early phases of an allergic inflammatory reaction

We investigated the presence of mast cell granules in macrophages following an in vivo model of an allergic reaction. Injection of ovalbumin (100 microg) into the peritoneal cavity of sensitised mice produced a rapid (within 2 h) influx of neutrophils followed by a slower (after >4 h) eosinophil migration. Ovalbumin treatment induced a high incidence (approximately 50%) of mast cell degranulation compared to control phosphated-buffered saline-treated mice. The majority (approximately 90%) of peritoneal macrophages contained mast cell granules as early as 2 h post-ovalbumin, with lower values at later time-points, as determined by staining with Toluidine blue and Berberine sulphate. This was confirmed by electron microscopy which enabled us to identify the complex mast cell granule sub-structural components in macrophage phagosomes. In conclusion, we used histochemical and ultrastructural analyses to show that mast cell granules become internalised with macrophages during the early stages of an experimental allergic reaction.     

Adriamycin Binds to the Matrix of Secretory Granules during Mast Cell Exocytosis

The antineoplastic drug adriamycin induces exocytosis in rat peritoneal mast cells followed by a significant uptake of the drug into the secretory granules. The drug is fluorescent, allowing visualization of its accumulation and binding to mast cell granules by fluorescence microscopy. At the same time, the well known inorganic dye ruthenium red was used as a probe because of its great affinity for heparin in the mast cell secretory granules as visualized by bright field microscopy. Competition between adriamycin and ruthenium red for binding to the negatively charged matrix of granules was demonstrated. Biochemical studies were also performed to confirm microscopic observations. Adriamycin may be of interest for studying mast cell secretion; it is not only a strong fluorescent dye for mast cell granules that are in communication with the extracellular space, but it also induces mast cell exocytosis.     

Selective fluorescence of zymogen granules of pancreatic acinar cells stained with hematoxylin and eosin.

Following staining with hematoxylin and eosin Y, paraffin sections of mouse pancreas were examined by transmitted light, epifluorescence and confocal laser scanning microscopy. Light microscopy revealed that the nuclei of pancreatic acinar cells were located basally, while the apices of the cells appeared eosinophilic, although the secretory granules were difficult to visualize. Under violet-blue light excitation, the zymogen granules at the apices of the acinar cells showed strong yellowish fluorescence; the other part of the cytoplasm was only faintly fluorescent and the nuclei and the supporting tissues were nonfluorescent. Confocal laser scanning microscopy resulted in clear pictures of the zymogen granules and their distribution within the cell. The fluorescent emission of zymogen granules was certainly the result of eosin Y staining, because hematoxylin is not a fluorochrome and the zymogen granules are not autofluorescent. Staining with eosin Y alone, however, did not result in clear fluorescent images of zymogen granules or any other cellular structures. Our observation shows that the fluorescence emission of eosin Y allows easy and precise recognition of zymogen granules of pancreatic cells.     

Selective fluorescence of zymogen granules of pancreatic acinar cells stained with hematoxylin and eosin

Following staining with hematoxylin and eosin Y, paraffin sections of mouse pancreas were examined by transmitted light, epifluorescence and confocal laser scanning microscopy. Light microscopy revealed that the nuclei of pancreatic acinar cells were located basally, while the apices of the cells appeared eosinophilic, although the secretory granules were difficult to visualize. Under violet-blue light excitation, the zymogen granules at the apices of the acinar cells showed strong yellowish fluorescence; the other part of the cytoplasm was only faintly fluorescent and the nuclei and the supporting tissues were nonfluorescent. Confocal laser scanning microscopy resulted in clear pictures of the zymogen granules and their distribution within the cell. The fluorescent emission of zymogen granules was certainly the result of eosin Y staining, because hematoxylin is not a fluorochrome and the zymogen granules are not autofluorescent. Staining with eosin Y alone, however, did not result in clear fluorescent images of zymogen granules or any other cellular structures. Our observation shows that the fluorescence emission of eosin Y allows easy and precise recognition of zymogen granules of pancreatic cells.     

Selective fluorescence of zymogen granules of pancreatic acinar cells stained with hematoxylin and eosin

Following staining with hematoxylin and eosin Y, paraffin sections of mouse pancreas were examined by transmitted light, epifluorescence and confocal laser scanning microscopy. Light microscopy revealed that the nuclei of pancreatic acinar cells were located basally, while the apices of the cells appeared eosinophilic, although the secretory granules were difficult to visualize. Under violet-blue light excitation, the zymogen granules at the apices of the acinar cells showed strong yellowish fluorescence; the other part of the cytoplasm was only faintly fluorescent and the nuclei and the supporting tissues were nonfluorescent. Confocal laser scanning microscopy resulted in clear pictures of the zymogen granules and their distribution within the cell. The fluorescent emission of zymogen granules was certainly the result of eosin Y staining, because hematoxylin is not a fluorochrome and the zymogen granules are not autofluorescent. Staining with eosin Y alone, however, did not result in clear fluorescent images of zymogen granules or any other cellular structures. Our observation shows that the fluorescence emission of eosin Y allows easy and precise recognition of zymogen granules of pancreatic cells.     

Staining Mast Cells for Morphometric Evaluation on an Image Analysis System

Multiple skin sections from three nonhuman primates (Macaca mulatta) and three hairless guinea pigs (Cavia porcellus) were stained with 12 different histologic stains to determine whether mast cells could be selectively stained for morphometric analysis using an image analysis system (IAS). Sections were first evaluated with routine light microscopy for mast cell granule staining and the intensity of background staining. Methylene blue-basic fuchsin and Unna's method for mast cells (polychrome methylene blue with differentiation in glycerin-ether) stained mast cell granules more intensely than background in both species. Toluidine blue-stained sections in the guinea pig yielded similar results. Staining of the nuclei of dermal connective tissue was enhanced with the methylene blue-basic fuchsin and toluidine blue stains. These two stains, along with the Unna's stain, were further evaluated on an IAS with and without various interference filters (400.5-700.5 nm wavelengths). In both the methylene blue-basic fuchsin and toluidine blue stained sections, mast cell granules and other cell nuclei were detected together by the IAS. The use of interference filters with these two stains did not distinguish mast cell granules from stained nuclei. Unna's stain was the best of the 12 stains evaluated because mast cell granule staining was strong and background staining was faint. This contrast was further enhanced by interference filters (500.5-539.5 nm) and allowed morphometric measurements of mast cells to be taken on the IAS without background interference.     

Cutaneous mast cell depletion and recovery in murine graft-vs-host disease

Mast cells as studied by light microscopy with metachromatic staining, have been noted to "disappear" from the skin of mice with chronic graft-vs-host disease (GVHD) produced across minor histocompatibility barriers. This mast cell disappearance is accompanied by ultrastructural evidence of loss of granule contents. In this study, we followed cutaneous mast cells in chronic GVHD over 9 mo by three methods: Light microscopy of toluidine blue-stained sections showed that mast cells not seen at day 42 reappeared between days 94 and 125, were supramaximal at days 146 and 164, and returned to normal levels at days 195 and 280. Double immunofluorescent staining of mast cells for the presence of surface IgE receptors and cytoplasmic granules (avidin) revealed IgE receptor-bearing cells that lacked avidin-binding granules at the time when mast cells were not apparent on light microscopy. By electron microscopy, reappearing mast cells have the morphology of immature dermal mast cells. Ultrastructural abnormalities of mast cells persist some 150 days after GVHD induction. The possible relationship of these mast cell changes to the development of dermal fibrosis in chronic GVHD is discussed.     

Metachromatic staining and electron dense reaction of glycosaminoglycans by means of Cuprolinic Blue

Summary The cationic phthalocyanin-like dye Cuprolinic Blue, unlike phthalocyanin dyes such as Alcian Blue or Astra Blue, can definitely exhibit a clear metachromatic reaction with appropriate substrates, The application of Cuprolinic Blue to epoxy-embedded semithin sections revealed that mast cell cytoplasmic granules, goblet cell mucin and cartilage matrix stained in violet shades (metachromatic), whereas nuclear chromatin presented a bright blue coloration (orthochromatic). The metachromatic structures showed a high degree of contrast when ultrathin sections treated with Cuprolinic Blue were examined by electron microscopy.Cytophotometric measurements of stained components from the large intestine showed different absorption maxima: at 580 nm for mucin and at 640 nm for nuclei. The spectroscopical analysis revealed a clear-cut metachromatic shift when the dye was in the presence of chondroitin—4-sulphate. The addition of aluminium metal to Cuprolinic Blue solutions resulted in a striking spectral change; under such conditions the dye showed absorption maximum at 530 nm.     

Buffered Romanowsky-Giemsa method for formalin fixed,paraffin embedded sections: taming a traditional stain

Romanowsky-Giemsa (RG) stains were devised during the 19th century for identifying plasmodia parasites in blood smears. Later, RG stains became standard procedures for hematology and cytology. Numerous attempts have been made to apply RG staining to formalin-fixed paraffin-embedded tissue sections, with varied success. Most published work on this topic described RG staining methods in which sections were overstained, then subjected to acid differentiation; unfortunately, the differentiation step often caused inconsistent staining outcomes. If staining is performed under optimal conditions with control of dye concentration, pH, solution temperature and staining time, no differentiation is required. We used RG and 0.002 M buffer, pH 42, for staining and washing sections. All steps were performed at room temperature. After staining and air drying, sections were washed in 96?100% ethanol to remove extraneous stain. Finally, sections were washed in xylene and mounted using DPX. Staining results were similar to routine hemalum and eosin (H &; E) staining. Nuclei were blue; intensity depended largely on chromatin density. RNA-rich sites were purple. Collagen fibers, keratin, muscle cells, erythrocytes and white matter of the central nervous system were stained pinkish and reddish hues. Cartilage matrix, mast cell granules and areas of myxomatous degeneration were purple. Sulfate-rich mucins were stained pale blue, while those lacking sulfate groups were unstained. Deposits of hemosiderin, lipofuscin and melanin were greenish, and calcium deposits were blue. Helicobacter pylori bacteria were violet to purple. The advantages of the method are its close similarity to H &; E staining and technical simplicity. Hemosiderin, H. pylori, mast cell granules, melanin and specific granules of different hematopoietic cells, which are invisible or barely distinguishable by H &; E staining, are visualized. Other advantages over previous RG stains include shorter staining time and avoidance of acetone.     

Supravital Uptake of Cationic Dyes by Mast Cell Granules: A Light and Electron Microscope Study

Methylene blue and neutral red were selected for staining mast cell granules by supravital injections. A new technique was applied for embedding in paraffin and Araldite® without dislocation or loss of dye. Stabilization and electron microscopic identification of the dyes were achieved by transforming them into electron-dense precipitates using phosphomolybdic acid dissolved in a paraformaldehyde-glutaraldehyde mixture to preserve the ultra structure of the tissues. It was found that in general the intensity of the light microscopic staining correlated directly with the electron density. Closer study revealed that not all cytoplasmic granules exhibited the same strong affinity for the cationic dyes. Furthermore, differences in dye distribution were observed within the granules themselves. The difference in the staining pattern can be explained by the heterogeneous occurrence of the anionic residues. Because of its high sensitivity and relatively low toxicity, the method described here is well suited for detecting the binding sites of organic cations in tissues under supravital or vital conditions     

Morphologic mast cell cycles

During ultrastructural studies of the early kinetics of anaphylactic degranulation and early and late recovery intervals from these release reactions induced in isolated, partially purified, cultured human lung mast cells stimulated to release histamine and granules by exposure to anti-IgE, we noted the ability of mast cells to undergo morphologic cycles. Following release of most cytoplasmic granules and shedding of large amounts of membranes and cellular processes, small, immature mast cells, nearly devoid of granules, were seen. These lymphocyte-like cells had condensed nuclear chromatin and large nucleoli. Blast transformation of these small cells and expansion of synthetic machinery-laden cytoplasm resulted in large, immature mast cells with small numbers of small, immature progranules and large numbers of lipid bodies in their cytoplasm. This cycle of mast cell morphologic change has considerable similarities to, as well as some differences from, lymphocyte morphologic cycles.     

Identification of a chymotrypsin-like proteinase in human mast cells

An antiserum was produced against a chymotryptic proteinase purified from human skin. The antiserum did not cross-react with human leukocyte cathepsin G and elastase, rat mast cell proteinase I, and human skin tryptase. Indirect immunofluorescent staining of frozen skin sections to localize the proteinase showed cytoplasmic staining of cells scattered about the papillary dermis and around blood vessels and appendages. Restaining these sections with toluidine blue revealed that the fluorescently stained cells contained metachromatically staining granules, the major distinguishing feature of mast cells. A similar correlation was found in lung tissue. Ultrastructural studies employing the ferritin bridge technique to immunologically identify the proteinase additionally localized the proteinase to mast cell granules. Biochemical and immunochemical characterization of chymotryptic activity solubilized from isolated human lung mast cells identified a chymotryptic proteinase that may be identical to the skin chymotryptic proteinase. These studies establish that human skin mast cells contain a chymotrypsin-like proteinase that is a granule constituent and provide evidence that indicates a comparable proteinase is also present in lung mast cells.