Differential Staining of Yeast for Purified Cell Walls, Broken Cells, And Whole Cells

Intact yeast cells are Gram positive but broken or disrupted cells are Gram negative. A counterstain with methyl green provides differential staining between cell wall and cytoplasm. The cells and cell fragments are dried on a slide and stained by a standard Gram stain. The preparation is then treated for 5 min with 1% phosphomolybdic acid, washed, and stained 0.5 min with 1% aqueous methyl green (unpurified by CHCl₃ extraction). Under these conditions whole, intact cells are dark purple or black, walls of broken cells and purified walls are light green, and the exposed cytoplasm stains light purple. All fractions can be easily differentiated.     

Basic Fuchsin and Picro-Indigo Carmine: A Selective Stain for Cells in Mitosis and for Autoradiography

Selective staining of dividing nuclei is accomplished as follows: paraffin sections, after hydration, are stained 15 min in a saturated aqueous solution of basic fuchsin, washed, then stained 1.5 min in an equal-volumes mixture of indigo carmine saturated in 70% alcohol, and saturated aqueous picric acid. Removal of excess dye with 3 changes of 70% alcohol, dehydration, clearing and covering in a resinous medium completes the process. Nuclei of dividing cells are stained red; cytoplasm and interphase nuclei, light green. This method has been used successfully for determining the mitotic activity of skin, kidney, liver and other rabbit and mouse tissues. Tissue sections previously prepared as autoradiographs may be stained by this method to facilitate the determination of radioactive labeling of mitotic cells.     

Sequential Use of Wright's and Ziehl-Neelsen's Stains for Demonstrating Phagocytosis of Bacterial Spores

Nongerminating spores, germinating spores, and vegetative cells of Clostridium botulinum type A were observed during phagocytosis in the peritoneal fluid of white mice. Since phagocytes are easily ruptured by heat, the method described avoids heating, as this has been employed in conventional spore staining methods. A thin smear of the fluid is air dried on the slide for 2 hr, and stained by Wright's method: stain, 2 min; dilution water, 2 min; and rinsed; then in 0.005% methylene blue for 30 sec, and rinsed. This is followed by Ziehl-Neelsen's stain for 3-4 min and destained with 1: acetone-95% ethanol for 10 sec. The slide is rinsed, and Wright's staining repeated: stain 1 min, dilution 2-3 min; and thereafter washed about 5 ml of Wright's buffer. Blotting and air drying completes the staining. Non-germinating spores stain light red with a red spore wall, germinating spores are deep red throughout, vegetative cells are blue, and leucocytes show a dark purple nucleus and light blue cytoplasm.     

Conjugates of Chitinase with Fluorescein Isothiocyanate or Lissamine Rhodamine as Specific Stains for Chitin In Sztu

The fluorescent chitinase technique is based on the specific affinity of the enzyme for its substrate and applicable when an enzyme can be coupled with a fluorescent dye. Fluorescent chitinase specifically stained chitinous structures in several fungi and an insect, but failed to stain other polysaccharides in bacterial and algal cell walls. Freezing-microtome sections of Drosophila and fungal mycelia 6 μ thick were fixed in acetone for 5 min, then stained and mounted in fluorescent chitinase. Staining of smears of unsectioned fungal material required 5 min in absolute acetone, 5 min in 95% ethanol-1 N aqueous acetic acid (1:1), 10 min in 0.2 M phosphate buffer, PH 5.7, 1 sec in enzyme-dye conjugate, and 10 min in carbonate-bicarbonate buffer (0.2 M, pH 10.7, for chitinase-FITC; pH 7.6, for chitinase-LRBC). Preparations are viewed microscopically with ultraviolet light.     

Staining Sections Coated with Radiographic Emulsion; A Nuclear Fast Red, Indigo-Carmine Sequence

The radioautographs consisting of emulsion-coated sections, after development, fixation and washing, are stained 3 min (uncritical) by an aqueous solution of 5% aluminium sulfate containing 0.1% nuclear fast red, then washed 2-5 min, and stained 5-10 sec by a saturated aqueous solution of picric acid to which 0.25% of indigo-carmine had been added. This technic stains differentially cell nuclei, cytoplasm, muscle fibers, connective tissues and borders of some epithelial cells. It is unnecessary to subject the slides to differentiating solutions.     

A Department Devoted to Abstracts of Books and Papers from Other Journals Dealing With Stains and Microscopic Technic in General

TO enable staining of insoluble calcium salts with glyoxal bis(2-hydroxyanil) (GBHA), the original solution containing 2 ml of 0.4% GBHA in absolute ethanol, and 0.3 ml of aqueous 5% NaOH, and limited to staining only soluble calcium salts, was modified as follows: 1, 2 ml of 0.4% GBHA in absolute ethanol in 0.6 ml of 10% aqueous NaOH; 11, 0.1 gm GBHA in 2 ml of 3.4% NaOH in 75% ethanol. To prevent diffusion and loss of calcium, the tissues were processed by the freeze-substitution or freeze-dry method and sections stained without removing the paraffin. Modification I is effective only when 1 or 2 drops placed on the section are evaporated gradually to dryness, concentrating the GBHA and NaOH on the insoluble calcium salts. Modification II is effective when dried or poured on the the section and allowed to stain for 5 min. The stained slides are immersed for 15 min in 90% ethanol saturated with KCN and Na₂CO₃ for specificity to calcium; rinsed and counterstained in 95% ethanol containing 0.1% each of fast green FCF and methylene blue; rinsed and dehydrated in ethanol; deparaffinized and cleared in xylene; and mounted in neutral synthetic resin. Although the modified methods tested on models failed to stain reagent grade CaCO₃ and Ca₃(PO₄)₂ crystals completely, apatite in developing vertebrae and calcified plaques in soft tissues were stained intensely red. The distribution of gross deposits of insoluble calcium salt in tissue sections corresponded with that shown in adjacent sections by the alizarin red S, ferrocyanide, and von Kossa methods. The modified GBHA method revealed smaller quantities of insoluble as well as soluble calcium salts discretely within cells where the other methods failed; also, calcium in cytoplasm of hypertrophied cartilage cells of developing vertebrae, and in cytoplasm of renal tubular cells of magnesium-deficient rats, not described previously, was demonstrated.     

The Glyoxal BIS(2-Hydroxyanil) Method Modified for Localizing Insoluble Calcium Salts

TO enable staining of insoluble calcium salts with glyoxal bis(2-hydroxyanil) (GBHA), the original solution containing 2 ml of 0.4% GBHA in absolute ethanol, and 0.3 ml of aqueous 5% NaOH, and limited to staining only soluble calcium salts, was modified as follows: 1, 2 ml of 0.4% GBHA in absolute ethanol in 0.6 ml of 10% aqueous NaOH; 11, 0.1 gm GBHA in 2 ml of 3.4% NaOH in 75% ethanol. To prevent diffusion and loss of calcium, the tissues were processed by the freeze-substitution or freeze-dry method and sections stained without removing the paraffin. Modification I is effective only when 1 or 2 drops placed on the section are evaporated gradually to dryness, concentrating the GBHA and NaOH on the insoluble calcium salts. Modification II is effective when dried or poured on the the section and allowed to stain for 5 min. The stained slides are immersed for 15 min in 90% ethanol saturated with KCN and Na₂CO₃ for specificity to calcium; rinsed and counterstained in 95% ethanol containing 0.1% each of fast green FCF and methylene blue; rinsed and dehydrated in ethanol; deparaffinized and cleared in xylene; and mounted in neutral synthetic resin. Although the modified methods tested on models failed to stain reagent grade CaCO₃ and Ca₃(PO₄)₂ crystals completely, apatite in developing vertebrae and calcified plaques in soft tissues were stained intensely red. The distribution of gross deposits of insoluble calcium salt in tissue sections corresponded with that shown in adjacent sections by the alizarin red S, ferrocyanide, and von Kossa methods. The modified GBHA method revealed smaller quantities of insoluble as well as soluble calcium salts discretely within cells where the other methods failed; also, calcium in cytoplasm of hypertrophied cartilage cells of developing vertebrae, and in cytoplasm of renal tubular cells of magnesium-deficient rats, not described previously, was demonstrated.     

Chemical composition of the yeast ascospore wall. The second outer layer consists of chitosan

In a preceding paper (Briza, P., Winkler, G., Kalchhauser, H., and Breitenbach, M. (1986) J. Biol. Chem. 261, 4288-4294), we reported the presence of dityrosine in the outer layers of yeast ascospore walls. Both outer layers seen in electron micrographs of yeast ascospore walls are sporulation-specific. Here we show that the second of these two outer layers consists of chitosan. In intact spores, it is shielded from staining with primulin by the outermost layer. However, in purified spore walls, the second layer is brightly stained by primulin, and hydrolysates of such preparations contain about 10% glucosamine relative to spore wall dry weight. The spore wall material staining with primulin is resistant to chitinase, but readily degraded by treatment with HNO2. Acetylation prior to HNO2 treatment completely prevents its degradation. A partial acid hydrolysate of spore walls contains predominantly soluble poly-beta-(1,4)-glucosamine as determined by 13C NMR spectroscopy. By these criteria, the glucosamine polymer of yeast ascospore walls is chitosan. As spore walls treated with alkali lack the inner layers but contain chitosan and as chitosan is not exposed at the surface of the spore, we conclude that it is localized in the second outer layer of the spore wall.     

Staining Tissue of the Central Nervous System with Luxol Fast Blue and Neutral Red

The tissue is fixed in 10% neutral saline formalin for 1 day to 3 wk depending on the size of the block, dehydrated and embedded in paraffin. The sections are stained at 57° C for 2 hr, then at 22° C for 30 min, in a 0.0125% solution of Luxol fast blue in 95% alcohol acidified by 0.1% acetic acid. They are differentiated in a solution consisting of: Li₂CO₃, 5.0 gm; LiOH-H₂O, 0.01 gm; and distilled water, 1 liter at 0-1° C, followed by 70% alcohol, and then treated with 0.2% NaHSO₃. They are soaked 1 min in an acetic acid-sodium acetate buffer 0.1 N, pH 5.6, then stained with 0.03% buffered aqueous neutral red. Sections are washed in distilled water, 1 sec, then treated with the following solution: CuSO₄·5H₂O, 0.5 gm; CrK(SO₄)₂·12H₂O, 0.5 gm; 10% acetic acid, 3 ml; and distilled water, 250 ml. Dehydration, clearing and covering complete the process. Myelin sheaths are stained bright blue; meninges and the adventitia of blood vessels are blue; red blood cells are green. Nissl material is stained brilliant red; axon hillocks, axis cylinders, ependyma, nuclei and some cytoplasm of neuroglia, media and endothelium of blood vessels are pink.     

F-actin and beta-tubulin localization in the myxospore stinging apparatus of Myxobolus pseudodispar Gorbunova, 1936 (Myxozoa, Myxosporea)

To understand the discharge mechanism of Myxozoan polar capsule (cnida) it is necessary to verify the role of major cytoskeletal proteins in the process. With this aim F-actin and beta-tubulin localization in spores of myxosporean developmental phase (in myxospores) of Myxobolus pseudodispar Gorbunova, 1936 has been studied under confocal scanning laser microscope using phalloidin fluorescent staining of F-actin and indirect anti-beta-tubulin immunostaining. F-actin has been detected in walls of the stinging tube invaginated into the polar capsule of myxospore. The fact suggests the contractile proteins involvement in the process of myxozoan polar capsule extrusion. In addition, the cytoplasm of amoeboid sporoplasm inside the spore cavity is stained by phalloidin. A polar cap with strong beta-tubulin immunoreacton is observed at the front pole of fully mature myxospore above the outlets of the polar capsule discharge channels. The role of the beta-tubulin cap is supposed to be similar to that of the cnidarian cnidocil made of microtubules. The weaker beta-tubulin immunoreactivity has been found in stinging tubes, in polar capsule walls as well as in the suture line of spore walls and in the cytoplasm of amoeboid sporoplasm. The involvement of cytoskeletal proteins in the process of polar capsule extrusion is discussed. A hypothesis on the myxozoan polar capsule discharge mechanism is suggested. The mechanism of myxozoan cnida discharge is compared with that of cnidaria.     

Direct Staining of Reticular Fibers with Gold Chloride

Reticular fibers are selectively stained in paraffin sections of formalin-fixed or Bouin's-fixed tissue as follows: 1% aqueous solution of gold chloride for 20 min, followed by a 10 min immersion in an aqueous solution containing 5% Na₂CO₃ and 0.5% KOH. The sections then are placed in a 5% aqueous solution of KI for 2 min. Counterstaining with a 0.25% aqueous solution of methylene blue chloride is optional. The reticular fibers stain dark pink; the collagen bundles are a light pink to straw color without the counterstain, or a light blue color when the methylene blue is used.     

A Simple Toluidine Blue—Basic Fuchsin Stain for Spermatozoa in Epoxy Sections

Differential staining of cell components of spermatozoa is readily accomplished in Epon or Araldite sections 0.5-1 μ thick from rat and hamster testis and epididymis, and stained as follows: 1% aqueous toluidine blue buffered at pH 6, 0.5-3 min at 90 C; washed in distilled water; 1% basic fuchsin in 50% alcohol, 3-5 min at 20-25 C; differentiated with 70% alcohol; allowed to dry; and mounted in a resin of high refraction (DPX was used). Results: acrosome, bright magenta; nucleus, deep blue; mitochondrial sheath of the middle-piece, pinkish purple; and tail, pale red. This procedure combined with staining of collagen by applying 2% aqueous phosphotungstic acid 1-2 min as a mordant, followed by 1% light green in 50% alcohol containing 1% acetic acid, 1-2 min at 20-25 C, gives polychromatic staining and is useful as a general stain for other epoxy-embedded tissues.     

Staining Plant Tissues with Chlorazol Black E and Pianese III-B

The staining schedule was developed for a study of the mycorrhizae of red pine, Pinus resinosa Ait. From 70% alcohol, sections are stained in a saturated solution of chlorazol black E in 70% alcohol, 10-30 min; free dye removed by washing in 95% alcohol; stained 18-24 hr in Pianese III-b; rinsed in 95% alcohol, acidified by the addition of 2 ml of saturated aqueous picric acid per 100 ml, 3-4 changes or until the last change is pale yellow or light green; and rinsing in 95% alcohol to remove the acid. If the acid fuchsin is too intense, a cautious differentiation with 95% alcohol containing 1-3% of a 0.1 N solution of NaOH is made. If too much chlorazol black is removed, the effect can be compensated by overstaining with this dye at the beginning of the process. Sections are dehydrated, cleared, and covered in the usual manner. This stain has applications to plant tissues generally, and is particularly effective for meristematic tissues. It shows details of cytoplasmic structures and gives sharp delineation of primary cell walls.     

A Combined Hcl-Acetic-Alcohol Fixation and Hydrolysis Followed by Cresyl Violet Staining for Mosquito Chromosome Spreads

Mosquito tissues of cytogenetical importance were dissected out on a slide in 0.65% NaCl, under a dissecting microscope, and treated about 30 sec in a drop of 1:3 Carnoy's fixative diluted 1:19 with distilled water. Fixing and hydrolysis was done by a single step in a mixture consisting of: glacial acetic acid, 1; ethanol 96%, 3; HCl conc., 2; and distilled water, 2 (v/v) for 2-6 min at 20-25 C. The specimen was then rinsed with the acetic-alcohol fixative and covered in a drop of 1% cresyl violet in 50% acetic acid under a coverslip coated with Mayer's albumen. Washing was performed immediately by adding water dropwise to one side of the coverslip and drawing the fluid from the other side with absorbent paper. The preparation could be used either as a temporary slide or made into a durable mount. The DNA-containing bands of the giant polytenic chromosomes stained dark violet; interband regions, weakly stained or colourless against a clear background. Mitotic and meiotic figures in gonadal cells stained selectively dark violet or violet with a practically unstained cytoplasm.     

An electron microscopic study of the mature megagametophyte in Zea mays

With light microscopy maize megagametophytes stained with Alcian blue-periodic acid-Schiff (AB-PAS) reveal acid or neutral polysaccharides in various cell walls. Comparative fine structural studies were made of permanganate- or OsO₄-fixed material. Organelle distribution is random in the vacuolate and multinucleate antipodal cells; organelles are abundant; starch is scarce. Antipodal cell walls have large openings forming several syncytia. Some walls are papillate. In the central cell (primary endosperm cell) a thin peripheral layer of cytoplasm surrounds the large vacuole; organelle number is moderate; starch is abundant. The central cell wall is also papillate adjacent to the antipodals and around the egg apparatus. In the synergids organelle distribution is non-random; nuclei and numerous organelles occupy the micropylar cytoplasm of each synergid; vacuoles dominate the chalazal cytoplasm of these cells. The filiform apparatus stains with AB-PAS and is composed of both lightly and darkly stained amorphous material. In the egg, organelle distribution is perinuclear with vacuoles proximal to the micropyle; mitochondria are large, abundant and polymorphic; starch is abundant. Nucleolar diameter is five times greater in the central cell and egg than in the antipodal cells and ten times greater than in the synergids. Plasmodesmata occur in all cell walls within the gametophyte, but none appear in the gametophyte wall itself. It is suggested that the antipodals and synergids might be secretory, the latter probably being involved in pollen tube attraction, and that stored metabolites in the central cell and egg cytoplasm support rapid increase in metabolism following fertilization.     

Permanent Smears of Leaf Tips for the Study of Chromosomes

Young leaf tips are soaked in a saturated aqueous esculin (aesculine) solution at 10-12° C for 15 min to 24 hr and fixed in acetic-alcohol, 1:1. The materials are then stained in a mixture of 2% aceto-orcein and 12V HCl (9:1), 3-4 sec over a flame followed by 30 min or longer at 30° C and then smeared in 1% aceto-orcein. Preparations are made permanent by loosening the cover glass in tertiary butyl alcohol and mounting directly in Canada balsam.     

Selective Staining of Protein and Starch in Wheat Flour and its Products

The main constituents of wheat flour and many wheat flour products are wheat protein (gluten) and starch granules. The specific staining of the protein present was effected by 10 min in 0.1% aqueous ponceau 2R (C.I. No. 16150) acidified with 3—4 drops of 1 N H₂SO₄ per 50 ml of staining solution, followed by rinsing in 2 changes of distilled water, dehydrating, clearing and mounting in a resinous medium in the normal way. Staining of starch was as follows: sections or flour smears were brought to water, treated for 10 min in a protein-blocking reagent (Taninol ADR—Imperial Chemical Industries—used in 1% aqueous solution) rinsed, then stained for 3 mins in 0.5% aqueous chlorazol violet R (C.I. No. 32445) or for 10 min in either 0.5% aqueous chlorazol violet N (C.I. No. 22570), or chlorazol black E (C.I. No. 30235). Staining was followed by thorough rinsing, normal dehydration and clearing and mounting in a medium of R.I. about 1.49 to enhance visibility of unstained starch grains. The methods are applicable to flour smears, cryostat and wax sections.     

Quad-Type Stain for the Simultaneous Demonstration of Intracellular and Extracellular Tissue Components

This technic for the simultaneous demonstration of several different tissue components works equally well on invertebrate and vertebrate tissue if they have been treated with nonchromate fixatives Sections 4-7 μ thick are stained 30 min in 1% Alcian blue, then treated with alkaline alcohol for 2 hr. They are stained in Verhoeff's hematoxylin for 4-6 hr, and rinsed in alcohol; stained in woodstain scarlet-acid fuchsin for 3 min, decolorized in 5% phosphotungstic acid for 20 min and finally stained 5-8 min in alcoholic saffron. Collagen and bone are stained yellow; elastin, myelin and nucleic acids, purple to black; muscle, chitin, cytoplasm, fibrinoid and acid secretion, bright red to lavender; ground substances and mucus, blue-green. Fibrous connective tissue, cartilage, bone and glandular epithelia are exceptionally well demonstrated by this method. Slides stained in this manner are well suited for color photomicrography and as demonstrations in the classroom.     

Bertalanffy-like fluorescence staining with 3-dimethylamino-6-methoxyacridine

Three new acridine dyes, 3-dimethylamino-6-methoxyacridine 1, 3-amino-6-methoxyacridine 2 and 3-amino-7-methoxyacridine 3, have been prepared and tested as fluorochromes of LM- and HeLa-cells. The dyes are basic compounds (pKA: 1 8,76; 2 8,01; 3 7,65) and form cations in neutral or acidic aqueous solutions by addition of a proton to the aza-nitrogen atom of the heterocycle. The fluorochromes stain fixed LM- and HeLa-cells at pH = 6. The fluorescence shows metachromasy similar to the staining with acridine orange AO according to the technique of Bertalanffy. But there is less fading of the fluorescence. The dye 1 is the most suitable fluorochrome of the series. It was studied in detail. Using optimized staining conditions the fluorescence of the nucleus is yellow-green that of the cytoplasm and the nucleoli orange or brownish-red. Enzymatic digestion experiments show that the dye cations are bound to DNA in the nucleus and to RNA in the cytoplasm or nucleoli. The absorption and emission spectra of the stained cells have been studied by means of microspectrophotometry. The absorption spectra of the nucleus and the cytoplasm are very similar. The maximum of the long wave length absorption of both occurs at 21400 cm-1 (467 nm) with a shoulder at ca 20100 cm-1 (498 nm). The fluorescence spectra of nucleus and cytoplasm of metachromatically stained cells are different. The emission maximum of the cytoplasm and nucleoli, 16200 cm-1 (617 nm), is red-shifted relative to the maximum of the nucleus, 18200 cm-1 (549 nm). This shift causes the metachromatic fluorescence effect. In addition we studied the concentration dependence of the absorption and fluorescence spectra of the cation 1 in aqueous solution, pH = 6, in the concentration range 6 X 10(-6)-6 X 10(-4) M. Shape and maximum of the long wave length absorption and emission depend only slightly on the concentration: Mean value of absorption maximum ca 21500 cm-1 (465 nm), shoulder at ca 20300 cm-1 (493 nm), fluorescence maximum ca 18300 cm-1 (547 nm). With growing concentration diminishes the molar absorptivity. This decrease in absorptivity and isosbestic points in the absorption spectra indicate the formation of dimers with growing dye concentration. The absorption spectra of the metachromatically stained cells and of the dye in aqueous solution are very similar.(ABSTRACT TRUNCATED AT 400 WORDS)     

Staining Streptomyces Scabies in Lesions of Common Scab of Potato

Toluidine blue can be used to stain Streptotnyces scabies distinctively in slide cultures or in the lesions of common potato scab. This staining method is based on the metachromaticism of volutin, a constant constituent of the spores and mycelium of S. scabies. Either sections or smears are fixed in FPA (formalin, 5 parts; propionic acid, 7.5; 50% alcohol, 87.5), stained in a 1:100 dilution of saturated aqueous toluidine blue from 20 minutes to 24 hours, dehydrated in an acetone-xylene series and mounted. Cellular constituents of the potato tuber stain blue or are colorless whereas the mycelium of Streptomyces appears as a series of red volutin spheres in the blue stained cytoplasm. The criteria of volutin and cytoplasmic staining along with the 1 µ diameter of the mycelium make it possible to distinguish Streptomyces from the other microorganisms and cells in the lesion region.