Ruthenium red as a stain for electron microscopy. Some new aspects of its application and mode of action

Summary Commercial ruthenium red has been tested for its purity by spectrophotometry. Impurities detected by this method could be abolished by nitric acid-precipitation of ruthenium brown. This substance has no effect on cell surface staining and converts almost completely to ruthenium red under the conditions used in electron microscopy. It was found, by photometric analysis, that in the ruthenium red-osmium tetroxide-cacodylate combination, generally used for cell surface staining, chemical reactions between ruthenium red and osmium tetroxide occur. As aerial oxidation of hexammineruthenium²⁺ leads to a product with some surface staining capability, it is suggested that an oxidazed product of ruthenium red is responsible for binding to cellular components, and that a reduced product of osmium tetroxide gives an additional contrast enhancement.In ruthenium red-osmium dioxide combinations ruthenium red seems to bind to cell surfaces without any molecular alteration, and contrast is gained by the model proposed by Blanquet (1976b). The latter method could open a way for investigating the binding of ruthenium red to certain natural compounds involved in calcium transport, as postulated by a number of authors.Both ruthenium-osmium combinations differ in their cell surface staining ability. The ruthenium red-osmium dioxide combination tends to form distinct subunits, whereas the osmium tetroxide variety stains homogeneously. In combination with osmium dioxide, the surface staining is affected by EDTA, and, in contrast to osmium tetroxide, a successive application of ruthenium red and osmium dioxide as possible.     

Ruthenium red as a stain for electron microscopy. Some new aspects of its application and mode of action.

Commercial ruthenium red has been tested for its purity by spectrophotometry. Impurities detected by this method could be abolished by nitric acid-precipitation of ruthenium brown. This substance has no effect on cell surface staining and converts almost completely to ruthenium red under the conditions used in electron microscopy. It was found, by photometric analysis, that in the ruthenium red-osmium tetroxide-cacodylate combination, generally used for cell surface staining, chemical reactions between ruthenium red and osmium tetroxide occur. As aerial oxidation of hexammineruthenium2+ leads to a product with some surface staining capability, it is suggested that an oxidized product of ruthenium red is responsible for binding to cellular components, and that a reduced product of osmium tetroxide gives an additional contrast enhancement. In ruthenium red-osmium dioxide combinations ruthenium red seems to bind to cell surfaces without any molecular alteration, and contrast is gained by the model proposed by Blanquet (1976b). The latter method could open a way for investigating the binding of ruthenium red to certain natural compounds involved in calcium transport, as postulated by a number of authors. Both ruthenium-osmium combinations differ in their cell surface staining ability. The ruthenium red-osmium dioxide combination tends to form distinct subunits, whereas the osmium tetroxide variety stains homogeneously. In combination with osmium dioxide, the surface staining is affected by EDTA, and, in contrast to osmium tetroxide, a successive application of ruthenium red and osmium dioxide as possible.     

Ruthenium Red-Mediated Osmium Binding for Examining Uncoated Biological Material Under the Scanning Electron Microscope

A simple technique for examining uncoated soft biological material under the scanning electron microscope is described. Rat tissues were initially fixed in 2.5% glutaraldehyde either by intravascular perfusion or by immersion. The samples were placed in buffered 2.5% glutaraldehyde containing 0.05% ruthenium red and postfixed in buffered 1% osmium tetroxide containing 0.05% ruthenium red. The samples were alternately incubated 3 to 5 times in 1% O₃O₄ and 0.1% ruthenium red solutions with continuous shaking at room temperature. The specimens were dehydrated, critical point dried, mounted and examined under the scanning electron microscope. Contour details were clearly defined at both the external and cut surfaces of the tissues. The specimens could be observed for more than 30 minutes without excessive charging or glow effects and the material remained stable under the beam at 20-25 kV and at various magnifications.     

Ruthenium red-mediated osmium binding for examining uncoated biological material under the scanning electron microscope

A simple technique for examining uncoated soft biological material under the scanning electron microscope is described. Rat tissues were initially fixed in 2.5% glutaraldehyde either by intravascular perfusion or by immersion. The samples were placed in buffered 2.5% glutaraldehyde containing 0.05% ruthenium red and postfixed in buffered 1% osmium tetroxide containing 0.05% ruthenium red. The samples were alternately incubated 3 to 5 times in 1% OsO4 and 0.1% ruthenium red solutions with continuous shaking at room temperature. The specimens were dehydrated, critical point dried, mounted and examined under the scanning electron microscope. Contour details were clearly defined at both the external and cut surfaces of the tissues. The specimens could be observed for more than 30 minutes without excessive charging or glow effects and the material remained stable under the beam at 20-25 kV and at various magnifications.     

The effects of various fixatives on the relative thickness of cellular membranes in the ventral lobe of the rat prostate

Synopsis A densitometric method was utilized in the measurement of the relative thickness of the cellular membranes in the ventral lobe of the rat prostate. Potassium permanganate, glutaraldehyde, osmium tetroxide, and ruthenium tetroxide solutions were used as fixatives. During preparation for electron microscopy, the tissues were given standardized treatments to reduce methodological errors; latex particles were applied to the thin sections to serve as reference particles of a known size. The most remarkable observation of the study was that the densitometric method yielded reproducible results and that the different fixatives gave significantly different values for the relative thickness of cellular membranes. Glutaraldehyde, or glutaraldehyde followed by ruthenium tetroxide post-fixation, gave the highest values for membrane thickness while osmium tetroxide and potassium permanganate gave the lowest values. Glutaraldehyde treatment, prior to osmium tetroxide or potassium permanganate post-fixations, rendered the membranes thicker than after osmium tetroxide and potassium permanganate treatments alone. Ruthenium tetroxide appeared to be very suitable for fixation of cellular membranes.     

Comparative effect of osmium tetroxide and ruthenium tetroxide on Penicillium sp. hyphae and Saccharomyces cerevisiae fungal cell wall ultrastructure

The fungal cell wall viewed through the electron microscope appears transparent when fixed by the conventional osmium tetroxide method. However, ruthenium tetroxide post-fixing has revealed new details in the ultrastructure of Penicillium sp. hyphae and Saccharomyces cerevisiae yeast. Most significant was the demonstration of two or three opaque diverse electron dense layers on the cell wall of each species. Two additional features were detected. Penicillium septa presented a three-layered appearance and budding S. cerevisiae yeast cell walls showed inner filiform cell wall protrusions into the cytoplasm. The combined use of osmium tetroxide and ruthenium tetroxide is recommended for post-fixing in electron microscopy studies of fungi.     

Comparison of chemical dehydration and critical point drying for the stabilization and visualization of aging biofilm present on interior surfaces of PVC distribution pipe

In this study, fixation of attached glycocalyx on the interior surfaces of polyvinyl chloride distribution pipe remnants was compared with and without ruthenium red/osmium tetroxide and, in the final preparatory phase, with chemical dehydration and critical point drying. SEM examination of interior surface of the polyvinyl chloride pipe showed varying concentrations of adherent bacteria, depending on the preparatory technique used. It was concluded that using a combination of ruthenium red/osmium tetroxide and critical point drying is the optimum method for visually demonstrating aging biofilm on the interior surface of contaminated polyvinyl chloride pipe.     

Preservation of Tracheal Mucus by Nonaqueous Fixative

Two nonaqueous fixatives, composed of fluorocarbon solvents with dissolved osmium tetroxide, were used to determine the feasibility of preserving the mucous coat in bovine and rat trachea for light and electron microscopy. Aqueous fixatives, while providing excellent cytological preservation, wash away the mucous lining, precluding ultrastructural analysis. Inclusion of ruthenium red or alcian blue within aqueous fixative improved retention of mucus, but provided incomplete, patchy results. Fixation with nonaqueous fluorocarbon solvent and dissolved osmium tetroxide preserved a continuous mucous epiphase layer above a clear hypophase layer. Subcomponents of the mucus included an electron dense surface layer, interrupted patches of mucus above the surface layer and electron dense membrane-like material within the mucus. This method of fixation will preserve mucus for light, scanning and transmission electron microscopy, using either intratracheal or immersion methods of fixation. The latter would enable use of materials from large animal models, autopsy or an abattoir.     

Ultrastructure of human leukocytes after simultaneous fixation with glutaraldehyde and osmium tetroxide and "postfixation" in uranyl acetate

Human leukocytes in suspension or in monolayer cultures have been processed for electron microscopy by fixation in a freshly made cold mixture of glutaraldehyde and osmium tetroxide and by "postfixation" in uranyl acetate. Simultaneous exposure to glutaraldehyde and osmium tetroxide eliminates many of the shortcomings seen when either of these agents is used alone as the initial fixative. Specimens are processed to the stage of dehydration as single cell suspensions or as very small clumps to assure rapid penetration of fixatives and efficient washing. The technique is rapid and reproducible. Electron micrographs presented in this report illustrate the ultrastructural features of human white cells prepared by this method.     

Block-staining tissues with potassium ferrocyanide-reduced osmium tetroxide and lead aspartate for electron microscopic radioautography

In the hope of devising a method for prestaining tissues en bloc for electron microscopic radioautography, pieces of radioiodine-labeled liver were taken through various combinations of ferrocyanide-reduced osmium tetroxide, lead aspartate, and aqueous uranyl acetate at room temperature or at 60 degrees C. Following the tests, the method adopted for routine use was to block-stain tissues for 2 hr in potassium ferrocyanide-reduced osmium tetroxide at 4 degrees C followed by 1 hr in Walton's lead aspartate at room temperature. This simple method, which requires no manipulation before or after emulsion coating and development of the radioautographs, provides adequate contrast without inducing background fog or artifacts.     

The fine structure of the glycocalyx of equine spermatozoa: a high-resolution cytochemical study.

Equine spermatozoa were obtained from ejaculates of young stallions. The seminal plasma was removed and the sperm pellets washed three times with 0-15 M-NaCl solution before final centrifugation at 4500 g for 15 min. The pellets were fixed in a mixture of 2-5% glutaraldehyde in 0-1 M-cacodylate buffer, pH 7-4, with 0-5% Alcian blue and post-fixed in 1% osmium tetroxide with 1% lanthanum nitrate; other samples were treated with ruthenium red. All samples were dehydrated in ascending concentrations of ethanol, embedded in araldite and thin sections examined in an electron microscope. Electron dense deposits of lanthanum were present on the surface plasmalemma of the head, mid-piece and tail of 70% of mature spermatozoa, and similar deposits were seen in ruthenium red-treated samples. No glycocalyx was observed in untreated spermatozoa.     

Pyrogallol red-vanadium complex—a new stain for electron microscopy

 We report on the application of a pyrogallol red-vanadium complex (PR-V) for ultracytochemical staining of proteinaceous structures in animal tissues and cell cultures. This dye may be used as a general purpose stain in electron microscopy. In contrast to osmium tetroxide, the price of the material is low and no toxic vapors are produced. The PR-V complex was prepared by addition of vanadium (IV) oxide sulfate to pyrogallol red dissolved in acetate buffer (pH 5.6). The formation of the complex was indicated by a color change from purple-red (λ_max=520 nm) to violet (λ_max=539 nm) which occurred at equimolar concentrations of the dye and the metal salt. Under these conditions PR-V was stable for several days. The mechanism of PR-V binding was checked in dot blots using different proteins as well as heparin for control. While heparin remained unstained, proteins were stained in a dose-dependent manner. Deamination of proteins with nitric oxide strongly reduced PR-V staining in dot blots as well as in cell cultures. Optimal staining results of animal cells and tissues were obtained in specimens that had been mildly fixed for at least 1 h or longer with a mixture of 0.1% glutaraldehyde and 1.0% paraformaldehyde dissolved in phosphate-buffered saline, pH 7.2, washed with acetate buffer, pH 5.6, and subsequently treated with PR-V in the presence of 50% ethanol at room temperature. Control specimens without PR-V but treated en bloc with uranyl acetate or sodium molybdate showed similar contrast but less details in the ultrastructure of the tissue. All specimens were embedded in epoxy resin and ultrathin sections were stained conventionally with uranyl and lead salt solutions. In electron micrographs, membrane-associated particles, stress fibers and filaments of the cell cortex, collagen fibrils, tight junctions and desmosomes, and other proteinaceous components were clearly visualized only in the PR-V-treated specimens. In conclusion, the ability to bind selectively and specifically to proteinaceous structures makes PR-V a versatile stain to study the localization and distribution of these structures in cells and tissues at the ultrastructural level. Accepted: 14 June 1996     

Metal compound intensification of the electron-density of diaminobenzidine

Diaminobenzidine (DAB), commonly used in immunocytochemistry as the substrate for peroxidase, has a low electron density. DAB has a known affinity for the salts of some metals and therefore an examination of the ability of six metal compounds (including osmium tetroxide) to increase the electron density associated with DAB deposits has been undertaken. Ultra-thin sections of unosmicated rat pituitary gland, embedded in L. R. White resin, were immunostained by a hapten sandwich immunoperoxidase method, using antibodies to ACTH and TSH. The unintensified electron density of the DAB polymer reaction product on the specific endocrine granules was compared with the electron density resulting from the use of each of the six metal compounds. Lead and silver nitrate gave unsatisfactory results, while phosphotungstic acid and uranyl acetate produced a limited increase in specific electron density under the conditions used. Gold chloride was found to give the highest electron density to the specific endocrine granules, followed closely by osmium tetroxide. Background staining was greater when osmium was used. We conclude that several metal compounds may be used to intensify the electron density of DAB, but of the ones tested, gold chloride, which is safer, more stable, and cheaper than osmium tetroxide, was clearly the best. This approach not only increases the electron density of the DAB reaction product, but allows of the possibility of quantitation using energy dispersive X-ray analysis.     

Ultrastructure of dyads in muscle fibers of Ascaris lumbricoides

The dyads of Ascaris body muscle cells consist of flattened intracellular cisternae applied to the sarcolemma at the cell surface and along the length of T-tubules. In specimens prepared by conventional methods (glutaraldehyde fixation, osmium tetroxide postfixation, double staining of sections with uranyl acetate and lead hydroxide), both the sarcolemma and the limiting membrane of the cisterna exhibit unit membrane structure and the space between them is occupied by a layer of peg-shaped densities which is referred to as the subsarcolemmal lamina. The lumen of the cisterna contains a serrated layer of dense material referred to as the intracisternal lamina. In specimens fixed in glutaraldehyde, dehydrated, and then postfixed in phosphotungstic acid, with no exposure to osmium tetroxide or heavy metal stains, the membranous components of the dyads appear only as negative images, but the subsarcolemmal and intracisternal laminae still appear dense. Except for the lack of density in membranes and in glycogen deposits, the picture produced by the latter method is very much like that of tissue prepared by conventional methods.     

Oxidation of pyrimidine nucleosides and nucleotides by osmium tetroxide

1. Pyrimidine nucleosides such as thymidine, uridine or cytidine are oxidized readily at 0° by osmium tetroxide in ammonium chloride buffer. There is virtually no oxidation in bicarbonate buffer of similar pH. Oxidation of 1-methyluracil yields 5,6-dihydro-4,5,6-trihydroxy-1-methyl-2-pyrimidone. 2. Osmium tetroxide and ammonia react reversibly in aqueous solution to form a yellow 1:1 complex, probably OsO₃NH. A second molecule of ammonia must be involved in the oxidation of UMP since the rate of this reaction is approximately proportional to the square of the concentration of unprotonated ammonia. 3. 4-Thiouridine reacts with osmium tetroxide much more rapidly than does uridine. The changes of absorption spectra are different in sodium bicarbonate buffer and in ammonium chloride buffer. They occur faster in the latter buffer and, under suitable conditions, cytidine is a major product. 4. Polyuridylic acid is oxidized readily by ammoniacal osmium tetroxide, but its oxidation is inhibited by polyadenylic acid. Pyrimidines of yeast amino acid-transfer RNA are oxidized more slowly than the corresponding mononucleosides, especially the thymine residues. Appreciable oxidation can occur without change of sedimentation coefficient.     

Osmium dependent argentaffin staining of lysosomes

Summary Lysosomes stain with the argentaffin reaction after fixation with glutaraldehyde followed by osmium tetroxide. The reaction works well both at the level of the light and electron microscope. Control experiments show that this argentaffinity is caused by reduced osmium tetroxide. No staining could be observed in freeze-dried material, in tissues fixed only with glutaraldehyde, or after bleaching of the sections with hydrogen peroxide solutions. In the electron microscope, the population of lysosomes appears heterogeneous as related to the density of silver deposits over the organelles. No correlation is found between size and argentaffinity of lysosomes. X-ray microanalysis of sections from glutaraldehyde/osmium tetroxide fixed material reveals significantly higher amounts of osmium in lysosomes, as compared to other cell organelles (e.g. peroxisomes or mitochondria). A significant peak for silver is observed in lysosomes after treatment of the sections with ammoniacal silver solution, whereas the signal for osmium is reduced. Amounts of sulphur are too low to be detected in lysosomes. It is concluded that argentaffin staining of lysosomes is an osmium dependent reaction.Parts of these results have been presented as a poster during the 20th Congress of Electron Microscopy, joint session of the Austrian Society of Electron Microscopy and the German Society of Electron Microscopy, August 23–28, 1981, Innsbruck, Austria     

Chemical analysis of osmium tetroxide staining in adipose tissue using imaging ToF-SIMS

Osmium tetroxide (OsO₄) is a commonly used stain for unsaturated lipids in electron and optical microscopy of cells and tissues. In this work, the localization of osmium oxide and specific lipids was independently monitored in mouse adipose tissue by using time-of-flight secondary ion mass spectrometry with Bi cluster primary ions. Substance-specific ion images recorded after OsO₄ staining showed that unsaturated C18 fatty acids were colocalized with osmium oxide, corroborating the view that osmium tetroxide binds to unsaturated lipids. In contrast, saturated fatty acids (C14, C16 and C18) and also unsaturated C16 fatty acids show largely complementary localizations to osmium oxide. Furthermore, the distributions of saturated and unsaturated diglycerides are consistent with the specific binding of osmium oxide to unsaturated C18 fatty acids. The abundance of ions, characteristic of phospholipids and proteins, is strongly decreased as a result of the osmium staining, suggesting that a large fraction of these compounds are removed from the tissue during this step, while ions related to fatty acids, di- and triglycerides remain strong after osmium staining. Ethanol dehydration after osmium staining results in more homogeneous distributions of osmium oxide and unsaturated lipids. This work provides detailed insight into the specific binding of osmium oxide to different lipids.     

PRESERVATION OF MYELIN LAMELLAR STRUCTURE IN THE ABSENCE OF LIPID : A Correlated Chemical and Morphological Study

The fine structure of myelin was studied in glutaraldehyde-fixed rat sciatic nerves depleted of lipid by acetone, chloroform:methanol (2:1 v/v), and chloroform:methanol:concentrated HCl (200:100:1, v/v/v). One portion of each of these nerves, plus the extracts, was saponified and analyzed by gas-liquid chromatography for fatty acids. The remainder of each nerve was stained in osmium tetroxide in CCl₄ (5g/100cc) and was embedded in Epon 812. Thin sections, examined in the electron microscope, revealed the preservation of myelin lamellar structure with a 170 A periodicity in nerves depleted of 98% of their lipids. Preservation of myelin lamellar structure depended on glutaraldehyde fixation and the introduction of osmium tetroxide in a nonpolar vehicle (CCl₄) after the lipids had been extracted. It is concluded that the periodic lamellar structure in electron micrographs of myelin depleted of lipid results from the complexing of osmium tetroxide, plus uranyl and lead stains, with protein.     

ENHANCEMENT OF IMMUNOGOLD-LABELLED FOCAL ADHESION SITES IN FIBROBLASTS CULTURED ON METAL SUBSTRATES: PROBLEMS AND SOLUTIONS

Visualisation of cell adhesion patterns by scanning electron microscopy requires special preparation and labelling. The membranes and cytoplasm must be removed, without damaging the antigen, to facilitate antibody access to vinculin in the focal adhesions. Low beam energy imaging is used to visualise the cell undersurface (embedded in resin after staining with osmium tetroxide) and immunogold-labelled adhesion sites. The gold probe, must be large enough (>40 nm) for detection, while viewing the whole cell, but large gold markers increase steric hindrance and decrease labelling efficiency. This problem can be overcome by using small gold probes (1-5 nm) followed by enlargement with silver enhancement, but osmium tetroxide stain etches the silver. We demonstrated that metal substrates increased this etching. Reducing the concentration of osmium tetroxide and incubation time reduced the amount of etching. We have demonstrated that gold enhancement was not etched by osmium tetroxide, irrespective of the substrate. Therefore, comparative studies of cell adhesion to different biomaterial substrates can be performed using immunogold-labelling with gold enhancement.     

A rapid technique for preparing microorganisms for transmission electron microscopy.

A rapid and efficient method of preparing microorganisms for transmission electron microscopy is reported. In developing the method Salmonella, streptococcal, and protozoal specimens were fixed with glutaraldehyde. After fixation cells are collected on a membrane filter, washed with buffer, postfixed with osmium tetroxide, then washed with distilled water and stained en bloc with uranyl acetate. Specimens are dehydrated using a graded series of acetone and then infiltrated with graded mixtures of acetone and Spurr embedding medium. Finally the membrane filter is cut into small pieces and embedded in fresh embedding medium polymerized in polyethylene capsules. By collecting and processing the specimens on membrane filters, numerous centrifugations are eliminated from standard procedures. The use of a low viscosity embedding medium allows for rapid infiltration and embedding of the specimen. Using this technique microbial specimens can be sectioned after less than 4 hours preparation.