Positive colloidal thorium dioxide as an electron microscopical contrasting agent for glycosaminoglycans,compared with ruthenium red and positive colloidal iron

Summary In electron microscopy Thorotrast has been used as a specific contrasting agent for acid glycosaminoglycans. Because of its high atomic number, thorium (Z=90) gives good contrast in the electron microscope, but at present it is less frequently used for this purpose. We prepared a positive colloidal solution of ThO₂ without stabilizers to compare its properties with those of ruthenium red and positive colloidal iron for contrasting fetal mouse epiphyseal cartilage. The results indicate that colloidal ThO₂, which is easy to prepare in any laboratory, gives better results than ruthenium red and colloidal iron do in this kind of cartilage. Furthermore, as judged from data in the literature and obtained in our laboratory, it penetrates this tissue better than Thorotrast does, probably because of the absence of stabilizers.     

Microdistribution of alpha particles in pathological sections of tissues from thorotrast patients detected by imaging plate autoradiography

Thorotrast is a colloidal suspension of radioactive (232)ThO(2) that naturally emits alpha particles (90%), beta particles and gamma rays (10%). Thorotrast was used as a radiographic contrast agent in the 1930s-1950s; it caused liver cancer several decades after injection because of its life-long deposition and exposure. Determination of the amount and the distribution of radioactive thorium are essential for assessment of radiation risks. We visualized alpha particles on ordinary archival tissue sections using an imaging plate and a BAS5000 image analyzer. Furthermore, we confirmed that the imaging system is sensitive enough to detect alpha particles and accurate in measuring the total amount of thorium deposited in the organ from a single tissue section. This method revealed that the amount of thorium deposited in tumor tissue is correlated to that in non-tumor tissue. Thorotrast deposition was not associated with DNA damage determined by histochemistry. In combination with histological findings, it is suggested that radioactive thorium always migrates within the deposited organs by macrophages, and that the organs are evenly exposed to alpha particles.     

Scanning electron microscopy: Identification of mast cells by indirect cathodoluminescence

Summary The epithelial tissues of the rabbit gall bladder reacted for acid mucosaccharides were studied with the electron microscope. A series of acid mucosaccharide-containing ultrastructures of the gall bladder epithelium were observed in specimens treated with dialyzed iron, colloidal thorium and ruthenium red. In the epithelium stained with dialyzed iron, reactive ultrastructures are not only extra- but intracellular; the surface coat of the plasma membrane, pinocytotic vesicles, granules of secretion and certain elements of the Golgi apparatus. In the epithelial tissues stained by colloidal thorium or ruthenium red, the surface coat of the plasma membrane is the only ultrastructure which is reacted positively for the acid mucosaccharide stains. The present images of ultrastructural elements containing acid mucosaccharides are taken to indicate a multiple function of the substances in rabbit gall bladder epithelium and are well correlated with the results of previous light and electron microscopic studies on the gall bladder epithelium of various vertebrate species.     

Measurement of colloidal iron binding at low pH in cartilage using the proton microprobe

Summary Quantitative micro-PIXE analysis was performed on mouse embryo epiphyseal cartilage and on the rib cartilage of mature animals after incubation of sections with colloidal iron at pH 1.8. The iron content as well as that of sulphur and phosphorus and Fe/S, Fe/P ratios were determined. It was found that colloidal iron content was higher in the cartilage than in other tissues. The cartilage also displayed the highest content of sulphur. The Fe/S ratio was however not constant, being highest in the degeneration zone close to the mineralization front, where the binding of iron was strongest while the amount of sulphur decreased. This indicates that factors other than number of sulphate groups influence the binding of positively charged molecules to glycosaminoglycans. This is confirmed by differences in the results obtained for embryonic and mature rib cartilage.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0 degree C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37 degrees C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.3 approximately 3 micron thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 200 approximately 1,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0 degree C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37 degrees C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stereomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Ruthenium Red and the Bacterial Glycocaly

Ruthenium red, a promising cationic reagent for electron microscopy (EM), has long been an important tool in histology. The reagent was initially used by botanists as a semispecific stain for pectic substances, but it has gradually been embraced by investigators in microbiology and the animal sciences as a stain for anionic glycosylated polymeric substances. Luft developed a reliable method and demonstrated that ruthenium red was a useful reagent for visualizing ultrastructural detail. Many investigators, using modifications of Luft's approach, have identified numerous applications for this important reagent. Ruthenium red has been used to show the ultrastructural detail of bacterial glycocalyces. Strong, sharp and consistent observations of this ultrastructural component of the bacterial cell have given a better understanding its fibrous anionic matrix. Any variations in staining owing to artifactual alteration of the fine delicate ultrastructural features have been overcome by incorporation of diamine lysine into ruthenium red methods, thus providing flexible processing times under less than ideal laboratory sampling conditions. Ruthenium red has broad utility in the biological sciences, and in combination with lysine, it is an excellent EM stain for enhanced visualization of bacterial glycocalyx from culture or from clinical specimens.     

Localization of pyroantimonate-precipitable cation and surface coat anionic binding sites in developing erythrocytic cells and macrophages in normal human bone marrow

Summary The surfaces of developing erythrocytic cells and macrophages have been examined in normal human bone marrow by means of the pyroantimonate-osmium, ruthenium red and Thorotrast techniques for inorganic cations, surface glycoprotein-phospholipid complexes and surface anionic binding sites, respectively. No differences in the degree of surface coat reactivity were noted in the erythrocytic cells at different stages of maturation while pyroantimonate binding to the plasmalemma was not evident developmentally until the final stages of erythrocytic development. Rhopheocytotic invaginations proved to be chemically distinct from the remainder of the cell surface since they did not bind Thorotrast or pyroantimonate and gave more staining with ruthenium red. Pyroantimonate does not bind to the surface of macrophages and the binding of Thorotrast by these cells is less. Macrophage-erythrocytic cell contact zones did not stain with Thorotrast but stained with ruthenium red. The significance of these observations is discussed.Supported by Grant No. AM-HE-12084-14 from the National Institutes of Health, Bethesda, Maryland. — Appreciation is expressed to Anita Topson and Marjorie Griffith for their technical assistance and to Dr. Robert Hilberg for performing the bone marrow aspirations.     

An electron microscopic investigation of the surface coat of the electrocyte of Electrophorus electricus

Summary The surface coat of the electrocyte of the main electric organ of Electrophorus electricus was studied using cytochemical methods (periodic acid-silver methenamine, periodic acid-chromic acid-silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, Concanavalin A — horseradish peroxidase, ruthenium red, Alcian-blue lanthanum nitrate, colloidal iron hydroxide and cationized ferritin). The surface of the electrocyte presents perpendicularly oriented tubular invaginations of the cell membrane. The fibrous coat 50–100 nm thick, penetrates into the lumen of the invaginations. It is also observed in the synaptic clefts existent in the posterior face of the electrocyte. The coating of the surface membrane gives a positive reaction with all techniques used. Binding of colloidal iron hydroxide particles was observed only in the outer layer of the coat. With the Alcian-blue lanthanum nitrate technique, microtubules were observed in the cytoplasm of the electrocyte.The results indicate that the surface coat of the electrocyte contains mucopolysaccharides, glycoproteins, acid mucopolysaccharides and anionic sites detected at low (colloidal iron hydroxyde) and neutral (cationized ferritin) pH.This work has been supported by Conselho Nacional de Desenvolvimento Cientifico e Tecnológico (CNPq), Conselho de Ensino e Pesquisa da UFRJ (CEPG) and Banco Nacional de Desenvolvimento Econômico     

Electron histochemistry and ultrastructural localization of carbohydrate-containing substances in the sheath of Volvox.

The location and characteristics of carbohydrate-containing structures within the intact sheath of Volvox were studied by 3,3'-diaminobenzidine tetrahydrochloride-osmium, colloidal iron, colloidal thorium, ruthenium red and periodic acid-silver methenamine staining. The sheath consists of external and internal fibrillar layers separated by a tripartite structure. The external layer reacts positively with 3,3'-diaminobenzidine tetrahydrochloride, colloidal iron, colloidal thorium and ruthenium red, indicating that it contains acid mucosaccharides. Staining in the external layer is abolished by Ba(OH)2 treatment. The tripartite structure and internal fibrillar layer contain periodic acid reactive groups which do not occur in the external layer. Under certain conditions, reactions between the cationic dyes and the internal material were also observed. It is postulated that the internal matrix of the sheath contains glycoproteins or a mixture of acid mucosaccharides and glycoproteins. Possible functions of the sheath material are discussed.     

Uptake of colloidal thorium dioxide by the mouse connective tissue mast cell.

The ability of the mouse mast cell to phagocytize colloidal thorium dioxide, Thorotrast, was investigated employing the mouse connective tissue air pouch. The connective tissue mast cell of mouse was found to have limited capability to ingest the particulate Thorotrast in comparison to the rat peritoneal mast cell which ingested this material readily. Fibroblasts and macrophages in the connective tissue removed injected Thorotrast very rapidly in contrast to mast cells that demonstrated limited phagocytic capabilities. The tissue mast cell of the mouse, therefore, should not be considered a part of the reticuloendothelial system.     

Electron microscopic observations of the surface of L-cells in culture

Summary Techniques are described for the preparation of preshadowed replicas of both the upper and lower surfaces of L-cells in culture, and of cross sections of L-cells growing on a cellophane substrate. These revealed long slender microvilli, 800 to 1,100 A in diameter, projecting from both upper and lower surfaces of the cells. These microvilli were frequently observed to contact other cells and substrate, and to leave material behind on the substrate. The plasma membrane of the lower surface was separated from the substrate by an electron-lucent gap 200 to 300 A wide. The surface coat of the L-cell was visualized by staining with colloidal iron and ruthenium. Staining with colloidal iron was most intense on the surface of the microvilli. The gap between cell and substrate was intensely stained with ruthenium red. Enzymatic digestion of living cells revealed that both trypsin and neuraminidase reduced the staining of the cell coat by colloidal iron, whereas only trypsin altered its staining with ruthenium red. After trypsin treatment, fragments of an amorphous material with the staining characteristics of the cell coat were observed between the denuded cells. Treatment with ribonuclease, chymotrypsin or hyaluronidase did not affect the staining of the cell coat.     

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.     

Ultracytochemical Modifications of Surface Carbohydrates in Fertilized Eggs of the Common Carp

The surface of the plasma membrane of unfertilized and fertilized carp eggs was examined by four cytochemical techniques, colloidal thorium, colloidal iron, ruthenium red and phosphotungstic acid stainings, to determine the carbohydrate moieties. The surface of the plasma membrane of unfertilized eggs stained only with colloidal iron, which was heterogeneously deposited: no deposits were seen on the plasma membrane near overlying cortical alveoli. In fertilized eggs, the membrane was stained by all four methods. These ultracytochemical modifications of the surface of the plasma membrane may be caused by participation of the limiting membranes of secretory organelles, probably by turnover of the inner surface of the limiting membranes. Neuraminidase treatment of fertilized eggs eliminated the deposits of colloidal iron on the surface of the plasma membrane and caused an increase in stainability with ruthenium red. Treatment with neuraminidase or trypsin prevented the staining with phosphotungstic acid.     

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.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Summary Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0° C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37° C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.33 m thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 2001,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0° C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37° C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stercomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

ELECTRON MICROSCOPE STUDIES ON THE SURFACE COAT OF THE NEPHRON

Attempts to make visible the carbohydrate coat at the free cell surface of glomeruli as well as the tubules of rabbit kidney were undertaken. The ruthenium red procedure was performed, according to Luft, at various pH values. Moreover, the colloidal iron and the colloidal thorium methods were used. Neuraminidase digestion was also performed. In the ruthenium red procedure the luminal face of the epithelial cells of the nephron was coated distinctly with reaction product. The results obtained revealed that some of the differences at various levels of the nephron depended on the pH values. In glomeruli and proximal convoluted tubules the optimum pH value was 7.4; in the ascending limb of Henle loops and distal convoluted tubules the optimum pH value was 6.8. The ruthenium red-positive surface coat was either closely connected with, or appeared as a part of, the outer leaflet of the unit membrane. The slit pores of glomeruli were also covered by a coat continuous with the surface coat of the adjacent foot processes. The coat lining the microvilli of proximal convoluted tubules completely filled the intervillous spaces. Also, both the colloidal iron method and the colloidal thorium method evidenced the presence of surface coat. Pre-treatment with neuraminidase abolished the effect of the Hale reaction. These results may indicate that the surface coat of the epithelia of the nephron shows the presence of glycoproteins containing siliac acid residues.     

The absorptive surface of Moniliformis dubius (Acanthocephala). II. Functional aspects

The functional nature of the acanthocephalan absorptive surface was further elucidated by a series of morphological and cytochemical studies with the electron microscope. The use of lanthanum nitrate and ruthenium red in fixatives and Thorotrast staining en bloc and on epoxy thin sections provided information about the surface coat and the surface crypts. Acid phosphatase was localized in the lumina of the crypts and in the five lysosomal types. In vitro studies utilizing ferritin, Thorotrast and horseradish peroxidase implicated the surface crypts in the digestion and/or uptake of large molecules. A consideration of the evidence suggests that these crypts are highly selective and specific in their function.     

Analysis of colloidal gold probes by isoelectric focusing in agarose gels

Colloidal gold particles of different size (3-20 nm in diameter) were prepared by tannic acid-citrate and citrate reduction methods. From these colloids, different probes were prepared using sheep anti-rabbit antiserum, sheep anti-rabbit IgG, bovine serum albumin, polyethylene glycol, and protein A as the primary stabilizers and polyethylene glycol and/or bovine serum albumin as secondary and tertiary stabilizers, in different combinations. The probes were analyzed by isoelectric focusing in agarose gels, which allow the migration of particles in the size range 3-20 nm. (P. Sewer and S. J. Hayes, 1986, Anal. Biochem. 158, 72-78). Isoelectric focusing revealed that the surface charge of colloidal gold probes is dependent upon the size of the gold particle, the reduction method used, the primary ligand, and the pH at which this is adsorbed, as well as upon the secondary and tertiary stabilizers used. It is proposed that such differences in surface charge may underlie the different results which may sometimes be observed in colloidal gold labeling, especially when novel ligands are used.     

The coating of mouse myocardial cells. A cytochemical electron microscopical study.

The coating of mouse myocardial cells has been investigated with a variety of cytochemical methods. The coating of the surface membrane gives a positive reaction with ruthenium red, colloidal thorium, phosphotungstic acid (PTA) at low pH, silver methenamine after periodic oxidation (PA-silver technique) and with silver proteinate after periodic oxidation and thiocarbohydrazide treatment (PA-TCH-silver technique). The coating of the T system gives almost similar results. The nexuses do not react with PTA nor with the PA-silver and PA-TCH-silver techniques, but they are strongly stained with ruthenium red which reveals periodic structures in their gaps. The specificities of the colloidal thorium technique and PAT staining have been tested by chemical treatments (methylation, acetylation, saponification), enzymatic digestions (pronase, trypsin, hyaluronidase, neuraminidase) and carbohydrate extractions (with 0.1 N NaOH and 0.05 M H2SO4). These cytochemical data indicate, considering the specificity of the reactions, that the coating of the membrane surface and the T system contains polyanionic groups. A part of them, at least, would belong to a carbohydrate-containing material (glycoproteins), whereas at the level of nexuses the sugar residues would probably be absent.     

An electron microscopic study of surface polysaccharides in Bacteroides

The electron microscopic appearance of the cell surface of Bacteroides strains and Klebsiella pneumoniae stained with ruthenium red or colloidal iron is described. The effect of polymyxin B (PMB) was also registered. It was found that all Bacteroides strains have a polysaccharide lined 'micro-capsule' external to the outer membrane which could aggregate and form blebs. The blebs so formed were distinct from other types of bleb formed in Klebsiella involving the outer membrane and induced by PMB. Such types of PMB alterations were not induced in Bacteroides.