Staining Juxtaglomerular Granules with Basic Fluorescent Stains

Many basic fluorescent dyes stain juxtaglomerular granules to produce characteristic colors in ultraviolet light. The stain is applied to paraffin sections of tissues fixed in 2% calcium acetate-10% formalin or in phosphate-buffered 10% formalin. Procedure: Bring section to water, stain 0.5 min in Delafield hematoxylin, wash in tap water, stain 3 min in a 0.1% aqueous solution of basic fluorescent dye (auramine O, acriflavine, acridine orange, coriphosphine O, acridine yellow, phosphine E, thioflavine T, berberine sulfate, atebrine or rivanol) and differentiate 1 min in 0.1% acetate acid (or omit this step). After washing in tap water, air dry with or without subsequent mounting in a resin. Juxtaglomerular granules stain bright fluorescent yellow or orange against a dark background.     

A Simple Method of Staining Juxtaglomerular Granules in the Rat Kidney for High Resolution Light Microscopy

A simple method for the demonstration of juxtaglomerular granules in Epon embedded semithin (0.5-1 μm) sections has been developed as follows: sections are prepared as for routine electron microscopy except that before dehydration, the tissues are immersed in 0.5% uranyl acetate in Veronal acetate buffer (pH 5.0) overnight at room temperature. After sectioning on an ultramicro-tome, the semithin sections are briefly stained with toluidine blue-pyronin Y. After staining, the section is rinsed in running tap water and then air dried. Under a light microscope with a 40 × or a 100 × objective, the juxtaglomerular granules appear as deep purple particles and are thus easily separated from the bluish cytoplasm of the juxtaglomerular cells. Cellular organelles in other cells of the kidney were also clearly stained and their fine structure distinguishable.     

Selective Staining of Mast Cell Granules with Chrysoidin

A simple chrysoidin stain (0.5% aqueous solution, 5-10 min) is selective for mast cell granules; alum-hematoxylin-chrysoidin stains histological features in addition to the granules and periodic acid-Schiff can be used for cytological and histochemical features. Selective chrysoidin staining is probably due to strong basophilia of mast cell granules.     

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:     

Fixative-Stain Sequences for Selective Demonstration of Juxtaglomerular Cells

The effects of 31 fixatives, containing alcohol, acids, formalin and metallic salts, and representing many of the standard fixatives, were observed for selectivity and intensity of staining of juxtaglomerular granules in mouse kidney. Four staining methods: 1:400,000 aqueous methyl violet 2B; Bowie's ethyl violet-Biebrich scarlet; 1:200,000 aldehyde fuchsin; and periodic acid-Schiff were used. Fixatives containing HgCl₂, trichloroacetic acid or formalin were found to be the most satisfactory for subsequent staining of the granules.     

The Staining of the Metachromatic Granules in Corynebacterium Diphtheriae

The metachromatic granules, which sometimes are regarded as characteristic of the diphtherial species, are more easily differentiated when the basic dye is made up in a solution of which the reaction is quite acid. Of the usual stains employed for demonstrating the granules, the Neisser stain proves to give the best results.     

üBisch Granules on Tapetal Membranes in Anthers; Rapid Selective Staining by Spirit Blue

Decapitate the anther and squeeze out its contents into a drop of water on a clean slide coated with Haupt's adhesive. Let slides air dry and stain the preparations for 4-6 hr in 0.005% spirit-soluble aniline blue, prepared in 50% ethanol. Pass the slides through acetone, 10 min; 1:1 mixture of acetone and xylene, 5 min; and xylene. Mount in a resinous medium. The technique is effective for both fresh anthers and anthers fixed in FAA, Carnoy's fluid, 1:3 acetic alcohol, and 10% formalin (commercial). For fixed anthers, follow customary methods of paraffin embedding and microtomy.     

The Selective Staining of Mitochondria

A critical analysis of extant selective mitochondrial stains has elucidated certain empirical criteria for the adoption of dyes for trial. These criteria include a specific triphenylmethane structure for the dye, with sulfonation and the use of aniline and heat as adjuvants. By the application of these characteristics the dyes fast green FGF and light green SF yellowish were chosen for study and proved to be highly selective mitochondrial stains. They are applicable to both tissue slices and homogenate studies and permit examination of the internal structure of mitochondria.     

Basic Fuchsin-Crystal Violet; A Rapid Staining Sequence for Juxtaglomerular Granular Cells Embedded in Epoxy Resin

A basic fuchsin-crystal violet staining sequence for demonstration of juxtaglomerular granular cells in epoxy-embedded tissues is rapid and results in slides with excellent contrast and intensity. Procedure: Cut sections 0.3-0.6 μ thick. Hydrate through xylene and alcohol to water. Stain in modified Goodpasture's stain (basic fuchsin, 1; aniline, 1; phenol, 1; 30% alcohol, 100) for 20-30 sec; rinse in tap water; stain in modified Stirling's (crystal violet, 5; alcohol, 10; aniline, 2; water, 88) for 20-30 sec; rinse in tap water and dry on a hotplate; mount in a synthetic resin. Granular cells of the juxtaglomerular apparatus are stained an intense dark blue by the crystal violet. Arterial elastic membranes and collagen are pale blue. Other structures are shades of red.     

Selective Staining of Volutin In Corynebacterwm Diphtheriae

Stain air-dried, heat-fixed smears of the usual Loefner-medium cultures of C. diphtheriae 5 min in 0.5% aqueous chrysoidin solution. Wash with water and apply Albert's iodine for 1 min. Wash with water and air-dry. Volutin stains brownish black or black, the bacterial body weak brown or yellow. There is no staining of nuclear structures.     

The Selective Staining of Red Blood Cells

A method for the selective staining of red blood cells is described. Material is fixed in 10% neutral formalin in .85% NaCl and imbedded in paraffin or celloidin. Sections 6-10 μ are stained 1-5 minutes in chromotrope 2R. Basophilic and the less strongly acidophilic elements are decolorized with 5% phosphotungstic acid in 95% ethyl alcohol. Red blood cells and other strongly acidophilic elements that may be present in the preparation retain the chromotrope 2R. A counterstain of methyl blue may be used for staining the decolorized basophilic elements. As a result, erythrocytes are stained red by the chromotrope 2R, and basophilic elements blue, by the methyl blue. Less strongly acidophilic elements, having little affinity for either primary or secondary dye, are colorless or gray.     

Staining of Bacterial Colonies on the Millipore Filter to Improve Contrast

About 5 ml of 1% blue tetrazolium in 70% ethyl alcohol were poured over mature colonies of Pasteurella pestis and Malleomyces pseudomallei on Millipore filters (MF), contained in the filter holder apparatus, and allowed to drain through with the suction applied. The MF was washed with water and then covered with about 10 ml of 0.001% aqueous trypan blue and drained. This technique provided vivid white colonies sharply defined against a blue background.

Another method utilized 0.1% quinacrine-HCl (Atabrine) to stain colonies yellow and 0.05% vital red to stain the MF pink to light red.     

Critical Staining of Pancreatic Alpha Granules with Phosphotungstic Acid Hematoxylin

Mammalian pancreatic alpha granules were differentially stained with phosphotungstic acid haematoxylin. Paraffin sections were dewaxed and hydrated, oxidised 5-40 sec in freshly prepared 0.3% KMnO₄ acidified with 0.3% (w/v) H₂SO₄, decolourised in 4% potassium metabisulphite, mordanted 20 min to 2 hr in 4% iron alum, stained in phosphotungstic acid haematoxylin 16-48 hr, rinsed in 95% ethanol until no stain runs from the tissue, dehydrated in absolute ethanol, cleared in xylene, and covered in synthetic resin. Advantages of this procedure are: (1) consistent, reproducible staining; (2) applicability to all the common laboratory mammals and man; (3) wide latitude at each stage, permitting its use as a routine method; and (4) superior visualization of alpha granules, due to suppression of background staining and absence of glare. For fixation, formalin-acetic or Bouin's solution is recommended.     

Peroxidase Staining Combined with Autoradiography for Study of Eosinophilic Granules

Giemsa staining and a peroxidase reaction were applied to blood films in conjunction with autoradiography to establish the types of granulocytes that stain differentially with the benzidine-peroxidase reaction. Differential counts made on Ciemsa-stained and peroxidase-stained autoradiograms were compared. In T. spiralis-infected rats with an elevated eosinophil count, as judged by Giemsa staining, the percentage of granulocytes that stained more intensely with peroxidase was increased. The results suggested that the eosinophils were the intensely peroxidase-positive cells. Blood smears were stained for peroxidase before being coated with NTB₂ liquid emulsion. Although the blue color of the peroxidase reaction faded during photographic development, the color redeveloped when peroxidase-stained autoradiograms were stained once again after photographic development. It was found necessary to stain for peroxidase both before and after autoradiography. The correlation of Giemsa-stained and peroxidase-stained autoradiograms indicated that the peroxidase stain can be combined with autoradiography to obtain authentic results.     

The Chemical Nature of the Gallocyanin-Chrome Alum Staining Complex

The presence of gallocyanin residues in its chrome alum complex was verified by decomposition of the complex and analysis of the red dye produced. The gallocyanin: chromium ratio was established as 2:1 by the method of continuous variation and verified by gel filtration. Infrared spectroscopy indicated that the binding of the chromium involved the carboxyl groups of the dye.     

Elimination of Fat and Protein Prior to the Selective Staining of Bone

The technic of staining skeletal systems previously described is often unsatisfactory for fetal specimens of Aves, because of the large amount of fat and protein. The writer avoids this by introducing two preliminary steps: (1) The specimen is placed in equal parts of glycerin, 95% alcohol and distilled water, and 10% aqueous pepsin (with a drop of 6N HC1 added) injected into the yoik sac, with 2-3 hours incubation at 40^oC. (2) While in 5% aqueous KOH (with a few drops of 2% H₂O₂), the fat areas are injected with cellosolve; and the specimen is left in this solution until skeletal elements become clearly visible. Staining in alizarin red S then follows.     

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.     

Highly Selective Acridine and Ethidium Staining of Bacterial DNA and RNA

The acridine dyes acridine orange (AO) and coriphosphine O (CPO) and ethidium bromide (EtBr) were used to stain bacterial digests after electrophoresis in native and denaturing (SDS) polyacrylamide gels and were shown to stain DNA and RNA preferentially over other subcellular components in the gels. Vegetative cell digests of Bacillus subtilis, Escherichia coli, Micrococcus luteus, and Staphylococcus aureus showed intense staining of DNA with AO and CPO near the top of the gel, but little or no staining of other cellular constituents. EtBr stained both DNA and RNA in the gels. Protein standards and non-nucleic acid cellular constituents stained faintly with high concentrations (> 100 μM) of AO, lower concentrations (13.9 μM) of CPO, and did not stain with 0.5 μg/ml EtBr in denaturing gels. The complete set of cellular biochemicals was visualized by silver staining, while the protein subset was detected by Coomassie blue staining. The highest concentrations of AO (120 μM) and CPO (13.9 μM) were shown to detect purified DNA in gels with a sensitivity in the range of 25–50 ng per band. This work demonstrates the specificity of acridine and ethidium dyes for nucleic acids, while illustrating the level of non-nucleic acid-specific interactions with other cellular components by staining of electrophoretically separated cellular components in a gel matrix.     

A New and Permanent Staining Method for Starch Granules Using Fluorescence Microscopy

A fluorescence technique has been developed for observing starch granules in plant tissues. Sections are stained with a mixture of dyes which we have named F.A.S.G.A. from the initials of the Spanish names of its components (fucsina, alcian blue, safranina, glicerina, agua), and viewed by epifluorescence microscopy. The starch granules fluoresce greenish yellow, allowing the degradative state to be observed. Cell structures which do not fluoresce are also differentiated. The stain permits identification of other structures when examined by visible light microscopy and is relatively resistant to fading over time.