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.     

Evaluation of Preparation, Staining and Microscopic Techniques for Counting Incremental Lines in Cementum of Human Teeth

Apposition of cementum occurs in phases resulting in two types of layers with different optical and staining properties that can be observed by light microscopy. Narrow, dark staining incremental lines are separated by wider bands of pale staining cementum. The distance from one line to the next represents a yearly increment deposit of cementum in many mammals, and counting these lines has been used routinely to estimate the age of the animals. Incremental lines in cementum have also been observed in sections of human teeth, and the object of the present investigation was to examine a number of methods for preparing and staining them for counting. Longitudinal and transverse sections, either ground or decalcified, were cut from formalin fixed human dental roots, paraffin embedded or frozen, and stained using several techniques. The cementum was investigated using conventional light, fluorescence, polarized light, confocal laser scanning, interference contrast, phase contrast, and scanning electron microscopy. Incremental lines in the cementum could be observed in ground sections and, following decalcification, in both frozen and paraffin embedded sections. Toluidine blue, cresyl violet, hematoxylin, or periodic acid Schiff (PAS) stained incremental lines allowing differentiation by conventional light microscopy. Contrast was best using fluorescence microscopy and excitation by green light since the stained cemental bands, but not the incremental lines, fluoresced after staining with cresyl violet, PAS or hematoxylin and eosin. The results with other microscopic techniques were unsatisfactory. Since incremental lines are not destroyed by acids and stain differently than the remaining cementum, it is likely that they possess an organic structure which differs from the cementum. Incremental lines in human dental cementum could be observed best using decalcified sections stained with cresyl violet excited by green light.     

Histone differentiation and nuclear activity

When fast green and eosin are used in combination to stain histones, nuclei display different affinities toward the dyes, some binding fast green exclusively, others binding eosin exclusively, and still others, both stains. In a given tissue, the frequencies of nuclei exhibiting the different colors remain fairly constant over a wide range of staining conditions. Nuclei of cells of the same type may stain differently, but when they are in the same stage of development or state of activity they tend to stain alike. Xenopus erythrocyte nuclei stain bright pink. Condensed mitotic and meiotic chromosomes stain purple. In the grasshopper spermatocyte, the main body of the interphase nucleus stains bright green, but the condensed chromosome stains purple. The mole crab sperm contains several distinct histone-like proteins, that differ in their amino acid compositions, within separate areas of the cell. In these sperms, the lysine-rich histones bind eosin, while the protamine-like protein and arginine-rich histone bind fast green. In general, the eosin and fast green bind preferentially to the lysine and arginine rich histones respectively, when the dyes are permitted to compete with one another. In several systems, including spermiogenesis and erythropoiesis, the aquisition of an eosinophilic component by the nuclei accompanies the slowing of RNA synthesis, and it is suggested that there may be a causal relationship between the two events, the eosinophilic histone effecting RNA synthesis within the nucleus as a whole.     

Cytochemical characterization of the modified Guard procedure a regressive staining method for demonstrating chromosomal basic proteins

Summary A number of acidic dyes, including various fluorochromes, were substituted for biebrich scarlet in the modified Guard (1959) procedure, a regressive staining method which appears to demonstrate basic chromosomal proteins. These substitutions were made to test the possibility that dyes other than biebrich scarlet might provide advantages in sensitivity and/or contrast, or that more control could be exerted over the differentiation step in which solutions of phosphotungstic and phosphomolybdic acids (polyacids) are used.Of the dyes tested in this investigation, six were found to be especially suitable: procion brilliant blue, procion yellow, geranine G, brilliant sulfoflavine, eosin Y, and eosin B. While procion brilliant blue could be used as an absorption dye only, the other dyes were used more profitably as fluorochromes. The various dyes displayed considerable variability in the ease with which they could be displayed from substrates with polyacid solutions during the differentiation step. Procion brilliant blue, procion yellow, and geranine G were displaced gradually and thus resembled biebrich scarlet. In contrast, eosin B, eosin Y, and brilliant sulfoflavine were displaced more easily from all but the most highly condensed chromatin in substrates. Brilliant sulfoflavine yielded exceptionally bright and nearly selective fluorescence of consensed chromosomes in division, X chromosomes of grasshopper spermatocytes, and sperm heads.Weak, but selective fluorescence was observed when monazo sulfonated dyes, including ponta chrome violet SW, eriochrome black, diamond red, and ponta chrome blue black, were substituted in the modified Guard procedure. Similar results were obtained with solochrome cyanin R. As expected, these dyes seemed to function as weakly acidic dyes.     

Eosin-related fluorescence of acidophil pituitary cells

The examination of haematoxylin and eosin stained sections of normal and neoplastic pituitary glands under ultraviolet light illumination discloses fluorescence of acidophil cells. The distinction between prolactin and growth hormone-producing cells is not possible. Such fluorescence depends on previous eosin staining.     

Demonstration of lipofuscin and Nissl bodies in crystal violet stained sections using a fluorescence technique or pyronin Y stain

This paper presents two simple, reliable methods for identification of lipofuscin and Nissl bodies in the same section. One method shows that lipofuscin stained with crystal violet retains its ability to fluoresce and can be observed under the fluorescence microscope after the stain has faded. Fading is accompanied by a gradual increase in the intensity of the fluorescence and is complete in about 5 min. Exciting illumination from this part of the spectrum also substantially fades staining of other autofluorescing tissue elements, such as lipids. Nonfluorescing structures, such as Nissl bodies, remain stained. By changing from transillumination with tungsten light to epifluorescent illumination and vice versa, both types of structures--Nissl bodies and lipofuscin--can be identified in the same section. The second technique uses pyronin Y for staining Nissl bodies in preparations previously stained with crystal violet. Nissl bodies are stained pink but lipofuscin remains violet. Lipofuscin in these sections also remains autofluorescent after the crystal violet stain has faded under violet or near-UV light.     

Pneumonia Due to Mycoplasma in Gnotobiotic Mice IV. Localization and Identification of Mycoplasma pulmonis in the Bronchi of Infected Gnotobiotic Mice by Immunofluorescence and by Light Microscopy

The model of pneumonia produced by intranasal inoculation of Mycoplasma pulmonis in gnotobiotic mice provided the opportunity to study the localization and identification of the infecting organisms in the tissues by immunofluorescence techniques. Frozen sections of pneumonic mouse lung were fixed in acetone, layered with rabbit anti-M. pulmonis serum, washed, layered again with fluorescein-isothiocyanate-labeled goat anti-rabbit globulin, washed again, and examined by fluorescence microscopy. A bright line of fluorescence was seen at the bronchial epithelial surface, usually in a continuous layer. Occasional masses of fluorescence were seen in the polymorphonuclear leukocytic exudate in the bronchial lumen. Sections of tissues fixed in Helle's or 10% Formalin fixatives and stained with hematoxylin and eosin were reviewed by light microscopy and revealed a zone of blue-staining material composed of tiny coccoid bodies in the same locations at the bronchial epithelial surface as in the immunofluorescent preparations and in previously reported electron microscope studies.     

Understanding Romanowsky staining

Summary Normal blood smears were stained by the standardised azure B-eosin Y Romanowsky procedure recently introduced by the ICSH, and the classical picture resulted. The effects of varying the times and temperature of staining, the composition of the solvent (buffer concentration, methanol content, & pH), the concentration of the dyes, and the mode of fixation were studied. The results are best understood in terms of the following staining mechanism. Initial colouration involves simple acid and basic dyeing. Eosin yields red erythrocytes and eosinophil granules. Azure B very rapidly gives rise to blue stained chromatin, neutrophil specific granules, platelets and ribosome-rich cytoplasms; also to violet basophil granules. Subsequently the azure B in certain structures combines with eosin to give purple azure B-eosin complexes, leaving other structures with their initial colours. The selectivity of complex formation is controlled by rate of entry of eosin into azure B stained structures. Only faster staining structures (i.e. chromatin, neutrophil specific granules, and platelets) permit formation of the purple complex in the standard method. This staining mechanism illuminates scientific problems (e.g. the nature of toxic granules) and assists technical trouble-shooting (e.g. why nuclei sometimes stain blue, not purple).To whom offprint should be sent     

Visualization of fungi in histological sections

Deparaffinized kidney sections from mice infected with Candida albicans and lung sections from mice infected with Blastomyces dermatitides were stained with the stilbene derivative, Uvitex 2B (1%), and counterstained with haemalum and eosin. Fungi selectively stained with Uvitex 2B are visualized by blue fluorescence under incident illumination with ultraviolet light. Simultaneous or consecutive illumination with transmitted light permits the assignment of fluorescent fungi to haemalum-eosin-stained structures in the section. The most practical means of achieving a high optical contrast with Uvitex 2B in sections and good haemalum-eosin staining is to use the established haemalum-eosin technique, but with a solution containing both 1% eosin and 1% Uvitex 2B in place of eosin alone. Since Uvitex 2B stains all fungi investigated so far, it affords a simple, sensitive and inexpensive method of selectively detecting opportunistic fungal infections in conventional histopathology.     

Microscopical and Spectroscopic Studies on the Fluorescence of a Daunomycin–aluminum Complex

In this study, the spectroscopic features and microscopical applications of the fluorescent daunomycin-Al3+ complex have been analyzed. In the presence of Al3+, the absorption spectrum of daunomycin showed a deep bathochromic shift and new peaks at 529 and 566nm, whereas the fluorescence emission was considerably modified. The emission of daunomycin alone (peak at 560nm under optimal excitation at 470nm) decreased continuously from 0.5 to 24h after addition of Al3+ ions, and a new emission peak appeared at 580nm (optimal excitation at 530nm). Under the fluorescence microscope using green exciting light, nuclei from chicken blood smears and paraffin sections of rat embryos stained with daunomycin showed a weak emission, which greatly increased after treatment with Al3+ ions. The bright and stable fluorescence of chromatin DNA induced by daunomycin-Al3+ could be a valuable labelling method in fluorescence microscopy and DNA cytochemistry.     

Microscopical and spectroscopic studies on the fluorescence of a daunomycin-aluminum complex.

In this study, the spectroscopic features and microscopical applications of the fluorescent daunomycin-Al3+ complex have been analyzed. In the presence of Al3+, the absorption spectrum of daunomycin showed a deep bathochromic shift and new peaks at 529 and 566 nm, whereas the fluorescence emission was considerably modified. The emission of daunomycin alone (peak at 560 nm under optimal excitation at 470 nm) decreased continuously from 0.5 to 24h after addition of Al3+ ions, and a new emission peak appeared at 580 nm (optimal excitation at 530 nm). Under the fluorescence microscope using green exciting light, nuclei from chicken blood smears and paraffin sections of rat embryos stained with daunomycin showed a weak emission, which greatly increased after treatment with Al3+ ions. The bright and stable fluorescence of chromatin DNA induced by daunomycin-Al3+ could be a valuable labelling method in fluorescence microscopy and DNA cytochemistry.     

Demonstration of Lipofuscin and Nissl Bodies in Crystal Violet Stained Sections Using a Fluorescence Technique or Pyronin Y Stain

This paper presents two simple, reliable methods for identification of lipofuscin and Nissl bodies in the same section. One method shows that lipofuscin stained with crystal violet retains its ability to fluoresce and can be observed under the fluorescence microscope after the stain has faded. Fading is accompanied by a gradual increase in the intensity of the fluorescence and is complete in about 5 min. Exciting illumination from this part of the spectrum also substantially fades staining of other autofluorescing tissue elements, such as lipids. Nonfluorescing structures, such as Nissl bodies, remain stained. By changing from transillumination with tungsten light to epifluorescent illumination and vice versa, both types of structures—Nissl bodies and lipofuscin—can be identified in the same section. The second technique uses pyronin Y for staining Nissl bodies in preparations previously stained with crystal violet. Nissl bodies are stained pink but lipofuscin remains violet. Lipofuscin in these sections also remains autofluorescent after the crystal violet stain has faded under violet or near-UV light.     

Fluorescence microscopical visualization of elastic fibres using basic fuchsin

Summary We show that fluorescence microscopy after staining of tissue sections with basic fuchsin (BF) can be used successfully for the demonstration of elastic fibres. Using double staining with BF and antibodies reacting with microfibrils of elastic fibres (anti-SAP) we showed that BF reacts with the elastin core of elastic fibres and the elastin poor terminal branches of the subepidermal elastic fibre system. Small amounts of bound BF were easily seen by fluorescence microscopy (FL) but not by ordinary light microscopy. Both frozen sections and sections of paraffin embedded tissues could be stained. The BF-FL staining procedure is simple to perform and, due to its selectivity, it may be useful for detecting elastic fibres in various tissues at the light microscopical level.     

Staining Methods For Studying Ingredient Distribution In Baked Cakes

A method is described for preparing cake crumb for sectioning and staining. Previous to embedding, the fat was stained and fixed by exposing small blocks of cake to the fumes from a 5%, freshly-prepared, aqueous solution of osmic acid (OsO₄). This was followed by dehydration in ethyl alcohol and tertiary butyl alcohol, removal of air under vacuum and infiltration with paraffin.

Sections were cut 20 and 9Op thick and mounted with water.

Wax was removed by immersion in xylene. The sections were rehydrated in a series of ethyl alcohol dilutions, from concentrated to dilute, then transferred to distilled water.

Protein was then stained pink by immersion of the slides in an acidified 0.04% water solution of eosin Y, or starch was stained blue with a dilute aqueous solution of iodine. Ten grams iodine and 10 g. KI were dissolved in 25 ml. distilled water. This stock solution was diluted for use one to two hundred times.

The relationship between protein and starch was demonstrated by staining the sections with eosin, differentiating in 50% alcohol and staining with iodine.

When slides of cake crumb were prepared in this way, the fat was stained black, the protein bright pink and the starch granules a dark blue.     

Immunocytochemical localization of Δ3, Δ2-enoyl-CoA isomerase and NADPH-dependent-2,4-dienoyl-CoA reductase in rat kidney

Localization of ³, ²-enoyl-CoA isomerase (ECI) and NADPH-dependent-2,4-dienoyl-CoA reductase (DCR) in the rat kidney was investigated by immunocytochemical techniques. The kidneys were perfusion-fixed and embedded in Epon or LR White. For light microscopy, semi-thin sections of Epon-embedded materials were stained by the immunoenzyme technique after the epoxy resin was removed by treatment with sodium ethoxide. For electron microscopy, ultra-thin sections of LR White-embedded materials were stained by the protein A-gold technique. By light microscopy, the S1 segment of the proximal tubule was most heavily stained for ECI and DCR whilst S2 and S3 segments showed intermediate staining. A weak staining reaction was observed in the distal tubule and the medullary collecting tubule. In the cortical collecting tubule, heavily stained cells were present between weakly stained cells. By electron microscopy, gold particles showing the antigenic sites for ECI were confined mainly to the mitochondria, but few particles were observed in the peroxisomes. Gold labeling for DCR was localized both in the mitochondria and the peroxisomes. The labeling intensity of the peroxisomes was much higher than that of the mitochondria. The results suggest that metabolism of unsaturated fatty acids occurs mainly in the mitochondria and the peroxisomes of the proximal tubule in the kidney.     

Fluorescence microscopical visualization of elastic fibres using basic fuchsin

We show that fluorescence microscopy after staining of tissue sections with basic fuchsin (BF) can be used successfully for the demonstration of elastic fibres. Using double staining with BF and antibodies reacting with microfibrils of elastic fibres (anti-SAP) we showed that BF reacts with the elastin core of elastic fibres and the elastin poor terminal branches of the subepidermal elastic fibre system. Small amounts of bound BF were easily seen by fluorescence microscopy (FL) but not by ordinary light microscopy. Both frozen sections and sections of paraffin embedded tissues could be stained. The BF-FL staining procedure is simple to perform and, due to its selectivity, it may be useful for detecting elastic fibres in various tissues at the light microscopical level.     

Detection of proteins and sialoglycoproteins in polyacrylamide gels using eosin Y stain

An eosin Y staining technique that permits detection of various proteins, including membrane sialoglycoproteins, in polyacrylamide gels is described. The sensitivity of the eosin Y staining method is comparable to silver staining. In addition, there is an added advantage of the antigen icily of the stained proteins being retained in a Western blot. Details of the procedure to obtain optimal staining results are described.     

Pyronin Y as a fluorescent stain for paraffin sections

Pyronin Y has long been used, in combination with other dyes such as Methyl Green, as a differential stain for nucleic acids in paraffin tissue sections. It also forms fluorescent complexes with double-stranded nucleic acids, especially RNA, enabling semi-quantitative analysis of cellular RNA in flow cytometry. However, the possibility of using pyronin Y as a fluorescent stain for paraffin tissue sections has rarely been investigated. We herein report that in sections stained with Methyl Green–pyronin Y, red blood cells, elastic fibre of blood vessels, zymogen granules of pancreatic acinar cells, surface membrane of heptocytes and kidney tubular cells showed strikingly strong green and/or red fluorescence, while the nuclei of cells appeared non-fluorescent. The use of confocal laser-scanning microscope greatly improved the resolution and selectivity of the fluorescent images. Staining with pyronin Y alone gave similar results in terms of fluorescence properties of the specimens. Pretreatment of paraffin sections with RNase significantly reduced cytoplasmic pyronin Y staining as judged by transmission light microscopy, but it had little effect on the fluorescence intensity of red blood cells, elastic fibres and zymogenbreak granules.