Fluorescent Staining of Juxtaglomerular Cells in Frozen Sections

Enzymatic investigations of the juxtaglomerular apparatus often creates the need for visualisation of granulated juxtaglomerular cells (JGC) in preparations subjected to histochemical procedures. In our investigations, Pitcock and Hartroft's (1958) modification of Bowie's method and the Endes et al. (1969) combined trichrome staining proved to be inadequate when applied to fresh cryostat sections, or to formol- or glutaraldehyde-fixetl, gum sucrose-impregnated frozen sections. Friedberg and Reid's (1966) crystal violet procedure for waxembedded kidneys also failed to give uniformly reproducible results. In attempting to find a satisfactory technique for both enzyme and granule staining, we noted Janigan's (1965) and Haratla's (1969) observations on paraffin-embedded JGC, and tested the following fluorochromes: thioflavine T—Fluka, C. I. 49005; auramine O—Merck, C. I. 41000; acridine orange—E. Gurr, C. I. 46005; berberine sulfate—Fluka, C. I. 75160 on 10 μ sections of albino mouse kidneys prepared in 4 different ways as follows:     

Differential Staining of Gastric Glandular Cells

Fundus of stomach is fixed in 10% formalin (aqueous), Bouin's fluid or 5% trichloracetic acid (aqueous). It is embedded in paraffin, and 7μ sections are cut, mounted, deparaffinized and passed to 70% alcohol and then stained as follows: Mordant 3 min. in saturated Bismarck brown in 70% alcohol. Rinse in 70% alcohol, pass to distilled water, then overstain (2 hr.) in aniline blue, 0.5% solution in 2.5% acetic acid (aqueous). Precipitate the anilin blue with 0.5 ml. of 0.1% methyl violet solution (aqueous) dropped on die slide. Leave on 2 min. or less. Wash and differentiate in 70% alcohol. (Parietal cells dark blue). Stain 30 min. in a mixture of hematein, 0.10g.; A1C13 cryst., 0.05g.; and 70% alcohol 50 ml., prepared just before use and not filtered. Rinse in 70% alcohol and differentiate with an alcoholic extract of saffron (2 g. saffron pistils in 100 ml. 90% alcohol at 60°C. for 6 hr.) while observing the progress of differentiation microscopically. Dehydrate by dropping a 0.1 % solution of acetic acid in absolute alcohol on the section for 30 sec., followed by pure absolute alcohol, xylene, and covering in balsam.     

Improved Staining Procedures for Semithin Epoxy Sections of Plant Tissues

Improved and reliable methods are described for staining semithin sections of plant materials fixed in glutaraldehyde-osmium and embedded in epoxy resins. One-micron sections are fixed to slides, stained with a two-solution hematoxylin procedure or with a methylene blue-azure A combination, counterstained in aqueous safranin O, cleared, and mounted permanently. Basophilic tissue components arc stained gray to black by the hematoxylin and blue or purple by the methylene blue-azure A combination; all wall structures are colored by the safranin. With the procedures recommended, stains am sharp and intense, sections arc flat, wrinkling and loss are held to a minimum, and unsightly precipitates do not form.     

Elimination OF Distortion and Poor Staining in Paraffin Sections OF Plant Tissues

Three fixing solutions causing least distortion and bright staining of plant tissues are named. Glycerin dehydration causes less distortion than a series of alcohol concentrations; 95% alcohol removes some of the glycerin, sets the protoplasm and improves the staining. Absolute alcohol causes distortion and should be avoided. Pure chloroform, as a paraffin solvent, is followed by brighter staining but more distortion than are the butyl alcohols. A schedule resulting in minimum distortion is given. The results are shown in photomicrographs. Brightest staining follows the use of C. P. iron alum and hematoxylin. The use of a paper cup for very gradual change from one liquid to another and as a labor saver is described.     

Ninhydrin Staining of Tissue Sections

This method represents a considerable improvement over earlier ninhydrin procedures. Celloidin sections were stained after mounting in a medium which clears with incubation at 55 °C. There appears to be no reason why paraffin section cannot be used. The sections were not placed in a large volume of ninhydrin (0.25% triketohydrindene hydrate in n-butanol) but only a small volume was sprayed onto the slide. Distortion resulting from heating in boiling water to develop the color was avoided by a slower treatment of 3 days' incubation at 55 °C. The use of water as a solvent in staining is also avoided, thus minimizing the possibility of color migration and insuring against the development of the intensely colored products of the ninhydrin reaction that occur in aqueous solution. Slides need not be observed upon the day of preparation, since the color was stable for about a week after its formation.     

A Simple Methylene Blue-Azure Ii-Basic Fuchsin Stain for Epoxy-Embedded Tissue Sections

One micron-thick sections of tissues fixed in glutaraldehyde, or in glutaraldehyde followed by osmium tetroxide, and embedded in a variety of plastic resins were stained in a methylene blue-azure II solution at 65 C, then counterstained in 0.05% basic fuchsin in 2.5% ethanol at room temperature (24 C). Considerable variation was found in methylene blue-azure II staining times for different embedding media. Aged Epon-812 required less staining time than freshly polymerized blocks of Epon-812. The procedure is a simple, rapid staining technique suitable for photomicrography and tissue orientation for electron microscopy.     

Differential Staining for Cellulosic and Modified Plant Cell Walls

A simple method to enhance the staining of cell wall components for fluorescence microscopy is described. In stems of Nicotiana tabacum and needles of Pinus eldarica lignin, the cuticle and unsaturated lipids are indicated by a purple-red fluorescence while pectocellulosic components fluorescc pale blue.     

A Phloxine-Azure-Hematoxylin Sequence for Differential Staining of Cells in Pancreatic Islets

Sections of 6 μ from tissues fixed in Susa or in Bouin's fluid (without acetic acid) and embedded in paraffin were attached to slides with Mayer's albumen, dried at 37 C for 12 hr, deparaffinized and hydrated. The sections fixed in Susa were transferred to a I₂-K₁ solution (1:2:300 ml of water); rinsed in water, decolorized in 5% Na₂S₂O₃; washed in running water, and rinsed in distilled water. Those fixed in Bouin's were transferred to 80% alcohol until decolorized, then rinsed in distilled water. All sections were stained in 1% aqueous phloxine, 10 min; rinsed in distilled water and transferred to 3% aqueous phosphotungstic acid, 1 min; rinsed in distilled water; stained 0.5 min in 0.05 azure II (Merck), washed in water; and finally, nuclear staining in Weigert's hematoxylin for 1 min was followed by a rinse in distilled water, rapid dehydration through alcohols, clearing in xylene and covering in balsam or a synthetic resin. In the completed stain, islet cells appear as follows: A cells, purple; B cells, weakly violet-blue; D cells, light blue with evident granules; exocrine cells, grayish blue with red granules.     

Quick Staining Method For Frozen Sections

Since the advent and general acceptance of frozen sections in histological and pathological laboratories it has been necessary to devise methods for staining these sections. The usual method is fixing the tissue to a slide by the use of celloidin. This paper is an attempt to describe a permanent, quick method of staining frozen sections without distortion or mechanical tearing of the tissues.     

History of Modern Chromosomal Analysis. Differential Staining of Plant Chromosomes

Differential staining methods found extensive use in karyotype studies of many plant and animal species and provide for reliable identification of all chromosomes of the organism. Below we describe the most widespread methods and history of their advent. In addition, we discuss specific structure of the chromosomes and possible mechanisms responsible for differential segmentation.     

Differential Staining of Mucin Granules from Epoxy Resin Sections by a Phosphotungstic Acid-Methyl Green Procedure

After treatment of epoxy resin semithin sections from glutaraldehyde fixed rat large intestine with 5% aqueous phosphotungstic acid (PTA), staining with unpurified 0.2% solutions of methyl green at 60 C for 5 min produces a color differentiation between mucin granules of goblet cells. Some mucin granules and the glycocalyx appear deep green while the remaining granules, luminal mucin and collagen fibers are pink. The known contamination of unpurified methyl green with crystal violet seems to be responsible for the pink staining reaction of the latter structures, which also present an orange-red fluorescence under green exciting light. Electron microscopic observations show selective contrast of mucin granules which appear with a different amount of PTA deposits. This procedure is useful to reveal the heterogeneity of mucin granules in light and electron microscopy.     

Staining Plant Cells with Silver. III. The Mechanism

Silver does not stain all cytological structures with the same intensity. The chemical basis for differential silver staining is unclear, but differences in protein side groups available to react with silver are likely involved. These include amine, carboxyl, phosphate, sulfhydryl and hydroxyl moieties. Here we report an investigation of the chemical groups that could be involved in salt-nylon silver staining of onion root tip squashes. Based on the results, we conclude that SN silver staining primarily depends on the presence of tyrosine hydroxyl groups, and we propose a mechanism for staining.     

Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

Differential Staining of Calcified Tissues in Plastic Embedded Microtome Sections by A Modification of Movat's Pentachrome Stain

Movat's pentachrome I stain has been adapted and modified as a stain for Undecalcified bone sections. After embedding in methyl methacrylate, this procedure yields consistently good results, with an excellent and colorful contrast between mineralized and unmineralized compartments of both cartilage and bone. in addition, osteoblats, osteoclasts, and other cells and tissue components can easily be differentiated. the staining properties of the lacunar wall surrounding the osteocytes are considered to reflect various states of osteocytic activity. the method is especially useful for the study of bone growth and bone repair, and as a stain for conventional histomorphometry and computer-assisted image analysis in bone biopsies.     

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.     

An Efficient Staining Method for Ultrathin Sections

A staining method to handle simultaneously as many as 20 electron microscope grids is described. The devices used are easily constructed of readily obtained inexpensive materials. The volumes of stain and wash water required are very small and drying grids is simplified.