Contrasting of Lowicryl K4M thin sections

Summary A method is presented for increasing the contrast of cellular structures on ultrathin sections from tissues embedded in Lowicryl K4M. The method, designated UA/MC adsorption staining, is based on the uranyl acetate/methyl cellulose staining of thawed cryosections. Ultrathin Lowicryl K4M sections were exposed to a uranyl acetate/methyl cellulose solution and the excess solution was removed with filter paper, leaving the remainder to air dry on the section. Sections on the grids were then directly observed in the electron microscope. Parameters such as methyl cellulose and uranyl acetate concentrations, duration of staining, temperature and pH were all assessed for their effect on subsequent contrast formation. Conditions were achieved which yielded intense contrast of cellular membranes, basement membranes and extracellular matrix components usually not apparent in Lowicryl K4M thin sections routinely counter-stained with uranyl acetate and lead acetate. The enhancement of the contrast of these structures does not obscure colloidal gold particles used for immunocytochemistry or lectin labeling, thus making the UA/MC adsorption staining method useful for increasing membrane contrast in routine post-embedding immuno- and lectin cytochemistry on Lowicryl K4M thin sections.     

Contrasting of Lowicryl K4M thin sections.

A method is presented for increasing the contrast of cellular structures on ultrathin sections from tissues embedded in Lowicryl K4M. The method, designated UA/MC adsorption staining, is based on the uranyl acetate/methyl cellulose staining of thawed cryosections. Ultrathin Lowicryl K4M sections were exposed to a uranyl acetate/methyl cellulose solution and the excess solution was removed with filter paper, leaving the remainder to air dry on the section. Sections on the grids were then directly observed in the electron microscope. Parameters such as methyl cellulose and uranyl acetate concentrations, duration of staining, temperature and pH were all assessed for their effect on subsequent contrast formation. Conditions were achieved which yielded intense contrast of cellular membranes, basement membranes and extracellular matrix components usually not apparent in Lowicryl K4M thin sections routinely counter-stained with uranyl acetate and lead acetate. The enhancement of the contrast of these structures does not obscure colloidal gold particles used for immunocytochemistry or lectin labeling, thus making the UA/MC adsorption staining method useful for increasing membrane contrast in routine post-embedding immuno- and lectin cytochemistry on Lowicryl K4M thin sections.     

Forming and Removing Stain Precipitates on Ultrathin Sections

Stain precipitates resulting from the use of lead or uranyl salts, or both, on ultrathin sections can be classified as belonging to one of three morphological types: I) extremely electron-dense particles caused by prolonged use of lead salts only, II) amorphous networks formed following double staining with either aqueous or alcoholic uranyl and lead salts, and III) crystalline needles sometimes resulting from double staining with alcoholic uranyl and lead salts. It has been found, however, that either acetic acid or aqueous uranyl acetate can be used to remove type I and type II precipitates from sections, and that oxalic acid and alcoholic uranyl solution will remove type II precipitates. Unfortunately, type III precipitates are unaffected by any agents tested so far.     

Forming and removing stain precipitates on ultrathin sections

Stain precipitates resulting from the use of lead or uranyl salts, or both, on ultrathin sections can be classified as belonging to one of three morphological types: I) extremely electron-dense particles caused by prolonged use of lead salts only, II) amorphous networks formed following double staining with either aqueous or alcoholic uranyl and lead salts, and III) crystalline needles sometimes resulting from double staining with alcoholic uranyl and lead salts. It has been found, however, that either acetic acid or aqueous uranyl acetate can be used to remove type I and type II precipitates from sections, and that oxalic acid and alcoholic uranyl solution will remove type II precipitates. Unfortunately, type III precipitates are unaffected by any agents tested so far.     

PREFERENTIAL STAINING OF NUCLEIC ACID-CONTAINING STRUCTURES FOR ELECTRON MICROSCOPY

Oriented fibres of extracted nucleohistone were employed as test material in a study of satisfactory fixation, embedding, and staining methods for structures containing a high proportion of nucleic acid. Fixation in buffered osmium tetroxide solution at pH 6, containing 10^-2 M Ca⁺⁺, and embedding in Araldite enabled sections of the fibres to be cut in which the orientation was well preserved. These could be strongly stained in 2 per cent aqueous uranyl acetate, and showed considerable fine structure. Certain regions in the nuclei of whole thymus tissue could also be strongly stained by the same procedure, and were identical with the regions stained by the Feulgen procedure in adjacent sections. Moreover, purified DNA was found to take up almost its own dry weight of uranyl acetate from 2 per cent aqueous solution. Strongest staining of whole tissue was obtained with very short fixation times-5 minutes or so at 0°C. Particularly intense staining was obtained when such tissue stained in uranyl acetate was further stained with lead hydroxide. Although the patterns of staining by lead hydroxide alone and by uranyl acetate were similar in tissues fixed for longer times (½ hour to 2 hours, at 0°C or 20°C), in briefly fixed material the DNA-containing regions appeared relatively unstained by lead hydroxide alone, whilst often there was appreciable staining of RNA-containing structures. Observations on the staining of some viruses by similar techniques are also described.     

Ultrastructural staining with sodium metaperiodate and sodium borohydride.

This article describes new ultrastructural staining methods for osmicated tissues based on the incubation of sections with sodium metaperiodate and sodium borohydride solutions before uranyl/lead staining. Sections incubated with sodium metaperiodate and sodium borohydride, treated with Triton X-100, and stained with ethanolic uranyl acetate/lead citrate showed a good contrast for the nucleolus and the interchromatin region, whereas the chromatin masses were bleached. Chromatin bleaching depended on the incubation with these oxidizing (metaperiodate) and reducing (borohydride) agents. Other factors that influenced the staining of the chromatin masses were the en bloc staining with uranyl acetate, the incubation of sections with Triton X-100, and the staining with aqueous or ethanolic uranyl acetate. The combination of these factors on sections treated with metaperiodate/borohydride provided a different appearance to the chromatin, from bleached to highly contrasted. Most cytoplasmic organelles showed a similar appearance with these procedures than with conventional uranyl/lead staining. However, when sections were incubated with metaperiodate/borohydride and Triton X-100 before uranyl/lead staining, the collagen fibers, and the glycocalix and zymogen granules of pancreatic acinar cells, appeared bleached. The possible combination of these methods with the immunolocalization of the amino acid taurine was also analyzed. (J Histochem Cytochem 50:11-19, 2002)     

Cytochemistry and morphology of synaptic structures in the cerebral cortex of rat.

Studies have been carried out on the synapses in the cerebral cortex of rat by using impregnation with ethanolic solution of phosphotungstic acid, contrast staining with ruthenium red and impregnation with bismuth iodide, with or without subsequent uranyl acetate and lead citrate staining. It has been established that dense projections are adequately visualized with methods demonstrating basic chemical groups (phosphotungstic acid and bismuth iodide), whereas the synaptic vesicles are stained by techniques demonstrating acid chemical groups (ruthenium red and uranyl acetate and lead citrate). On the basis of these observations a hypothesis is forwarded concerning the mechanisms of migration of synaptic vesicles towards the presynaptic membrane. Measurements of the parameters of the dense projections suggest that the configuration of the presynaptic vesicular grid is not uniform along the presynaptic areas.     

Negative staining of rat tail tendon collagen fibrils with uranyl formate

Negative staining of rat tail tendon collagen fibrils with uranyl formate appears to reveal more detail in the axial banding pattern than any other positive or negative staining method hitherto employed. In addition, uranyl formate and other uranyl solutions appear to reveal fine, closely spaced, longitudinal filaments which may represent the individual tropocollagen molecules.     

Lipid droplets in the adrenal cortex of the rat. Preservation after tannic acid—paraformaldehyde—glutaraldehyde fixation and extraction during staining

Adrenocortical tissue from the rat was fixed in glutaraldehyde-paraformaldehyde-tannic acid with or without potassium pyroantimonate. An electron opacity was observed in lipid droplets from unstained sections of tissue with or without antimonate in the fixative and is most likely attributable to inclusion of tannic acid in the fixative. The opacity was largely removed after staining with uranyl acetate in absolute methanol followed by lead citrate. Removal of the opacity is attributable to staining in lead citrate, not uranyl acetate, because highly basic solution without lead also removes the density. An electron-opaque rim is present at the interface of lipid droplet and cytoplasm, although no distinct membranous structure is observable. The rim may correspond to myelin-like structures seen sometimes in lipid droplets from adrenocortical cells fixed by routine procedures employing pre-fixation with glutaraldehyde and post-fixation with osmium tetroxide. Results of this study point to the conclusion that ultrathin sections should be examined unstained in the validation of a new regime for processing tissues in electron microscopy.     

The loss of enzyme reaction products from ultrathin sections during the staining for electron microscopy

Summary The effects of heavy metal salt staining procedures on the reaction products obtained in the demonstration of arylsulphatase and of acid phosphatase were studied.Lead citrate staining at pH 12 was found to cause a very marked dissolution of barium sulphate and a moderate dissolution of lead sulphate. The staining with uranyl acetate was found to dissolve moderately both barium and lead sulphate.Neither lead citrate nor uranyl acetate staining had any remarkable effect on lead phosphate.The mechanism of the dissolution and the possibilities to avoid it were discussed.     

Application of method of OTE staining of ultrathin sections based on example of microsporidia (Protozoa: Microsporidia)

A comparative analysis of ultrastructure of some organelles stained by different methods of staining of ultrathin sections has been performed using the example of intracellular parasites, i.e., microsporidia. The distinctive peculiarities are revealed and the advantages and disadvantages are substantiated of the traditional method of contrasting with uranyl acetate and the nontraditional method of contrasting using black Chinese tea extract, i.e., oolong tea extract (OTE). The OTE-staining method dies the basic intracellular structures of microsporidia, which is a matter of taxonomic significance; it also reveals additional layers of the polar filament with more distinct boundaries between them. However, traditional UA-staining better reveals some structures (membranes, layers of envelope of mature spores, structure of the rough endoplasmic reticulum, Golgi complex, nuclear chromatin) and provides for higher general contrast. The OTE solution is safe to use and can be longer kept in light at room temperature without losing its activity. However, the OTE-method is time-consuming. Hence, this staining method has both advantages and disadvantages. On the whole, it can be used as an alternative to the traditional staining with uranyl acetate.     

Uranyl-EDTA-hematoxylin: a new selective staining technique for nucleolar material.

This paper deals with the visualization of nuclear structures in glutaraldehyde fixed, acetic acid flattened preparations from Chironomus salivary glands, by means of an uranyl mordanting followed by hematoxylin staining. Under these conditions all the nuclear structures (bands, Balbiani rings, and nucleoli) were deeply stained. Treatment with 0.1 M EDTA for at least 30 sec after uranyl mordanting completely prevents the following hematoxylin staining in all the structures but the nucleolus. With increased EDTA extraction times (60-90 sec) the central region (composed of pars fibrosa) in spontaneously or experimentally segregated nucleoli showed the highest capacity for retaining uranyl ions. This selective staining of the nucleolar (possibly proteinic) material proved also efficient in cells from Drosophila testes and Allium roots.     

Kinetics of Lead Citrate Staining of Thin Sections for Electron Microscopy

The staining of thin sections with lead citrate shows an initial increase followed by a decrease much later; the rate of the initial increase and subsequent loss varies for different cellular components. The decrease eventually reaches a stable minimum. At this level electron scattering is less than that of unstained sections, demonstrating a loss of biological material.

Lead citrate used as a poststain following uranyl acetate causes an increase in electron density that is independent of staining time over 1-30 rain; this increase appears to depend only on the quantity of uranyl acetate already bound, implying that the lead binds predominantly to the uranyl acetate.     

ELECTRON STAINS : I. Chemical Studies on the Interaction of DNA with Uranyl Salts

Chemical studies have been carried out on the interaction of DNA with uranyl salts. The effect of variations in pH, salt concentration, and structural integrity of the DNA on the stoichiometry of the salt-substrate complex have been investigated. At pH 3.5 DNA interacts with uranyl ions in low concentration yielding a substrate metal ion complex with a UO₂⁺⁺/P mole ratio of about ½ and having a large association constant. At low pH's (about 2.3) the mole ratio decreases to about ⅓. Destruction of the structural integrity of the DNA by heating in HCHO solutions leads to a similar drop in the amount of metal ion bound. Raising the pH above 3.5 leads to an apparent increase in binding as does increasing the concentration of the salt solution. This additional binding has a lower association constant. Under similar conditions DNA binds about seven times more uranyl ion than bovine serum albumin, indicating useful selectivity in staining for electron microscopy.     

THE FINE STRUCTURE OF ELASTIC FIBERS

The fine structure of developing elastic fibers in bovine ligamentum nuchae and rat flexor digital tendon was examined. Elastic fibers were found to contain two distinct morphologic components in sections stained with uranyl acetate and lead. These components are 100 A fibrils and a central, almost amorphous nonstaining area. During development, the first identifiable elastic fibers are composed of aggregates of fine fibrils approximately 100 A in diameter. With advancing age, somewhat amorphous regions appear surrounded by these fibrils. These regions increase in prominence until in mature elastic fibers they are the predominant structure surrounded by a mantle of 100 A fibrils. Specific staining characteristics for each of the two components of the elastic fiber as well as for the collagen fibrils in these tissues can be demonstrated after staining with lead, uranyl acetate, or phosphotungstic acid. The 100 A fibrils stain with both uranyl acetate and lead, whereas the central regions of the elastic fibers stain only with phosphotungstic acid. Collagen fibrils stain with uranyl acetate or phosphotungstic acid, but not with lead. These staining reactions imply either a chemical or an organizational difference in these structures. The significance and possible nature of the two morphologic components of the elastic fiber remain to be elucidated.     

Staining of intracellular deposits of uranium in cultured murine macrophages.

In our studies of the health effects of internalized depleted uranium, we developed a simple and rapid light microscopic method to stain specifically intracellular uranium deposits. Using J774 cells, a mouse macrophage line, treated with uranyl nitrate and the pyridylazo dye 2-(5-bromo-2-pyridylazo)-5-diethylaminophenol, uranium uptake by the cells was followed. Specificity of the stain for uranium was accomplished by using masking agents to prevent the interaction of the stain with other metals. Prestaining wash consisting of a mixture of sodium citrate and ethylenediaminetetraacetic acid eliminated staining of metals other than uranium. The staining solution consisted of the pyridylazo dye in borate buffer along with a quaternary ammonium salt, ethylhexadecyldimethylammonium bromide, and the aforementioned sodium citrate/ethylenediaminetetraacetic acid mixture. The buffer was essential for maintaining the pH within the optimum range of 8 to 12, and the quaternary ammonium salt prevented precipitation of the dye. Staining was conducted at room temperature and was complete in 30 min. Staining intensity correlated with both uranyl nitrate concentration and incubation time. Our method provides a simple procedure for detecting intracellular uranium deposits in macrophages.     

Staining of intracellular deposits of uranium in cultured murine macrophages

In our studies of the health effects of internalized depleted uranium, we developed a simple and rapid light microscopic method to stain specifically intracellular uranium deposits. Using J774 cells, a mouse macrophage line, treated with uranyl nitrate and the pyridylazo dye 2-(5-bromo-2- pyridylazo)-5-diethylaminophenol, uranium uptake by the cells was followed. Specificity of the stain for uranium was accomplished by using masking agents to prevent the interaction of the stain with other metals. Prestaining wash consisting of a mixture of sodium citrate and ethylenediaminetetraacetic acid eliminated staining of metals other than uranium. The staining solution consisted of the pyridylazo dye in borate buffer along with a quaternary ammonium salt, ethylhexadecyldimethylammonium bromide, and the aforementioned sodium citrate/ethylene-diaminetetraacetic acid mixture. The buffer was essential for maintaining the pH within the optimum range of 8 to 12, and the quaternary ammonium salt prevented precipitation of the dye. Staining was conducted at room temperature and was complete in 30 min. Staining intensity correlated with both uranyl nitrate concentration and incubation time. Our method provides a simple procedure for detecting intracellular uranium deposits in macrophages.     

The correlation between bismuth and uranyl staining and phosphorus content of intracellular structures as determined by electron spectroscopic imaging

Four groups of intracellular structures can be recognized according to bismuth and uranyl staining and phosphorus content. (1) Those which contain phosphorus and stain strongly with uranyl acetate but not with bismuth (ribosomes, heterochromatin and mature ribosomal precursor granules), presumably because of their nucleic acid content. (2) Those which contain phosphorus and stain with uranyl acetate and bismuth (interchromatin granules, immature ribosomal precursor granules and mitochondrial granules), presumably because at least some of their phosphate is available to react with bismuth. (3) Those which contain little phosphorus but which stain strongly with bismuth and weakly with uranyl acetate (Golgi complex beads), perhaps because some ligand in addition to phosphate reacts with bismuth, and (4) those which do not contain phosphorus and stain with neither uranyl acetate nor bismuth (portasomes). Uranyl staining correlates strongly with the phosphorus content of nucleic acids, proteins and inorganic deposits. Bismuth will stain some phosphorylated molecules but not all. Thus only some phosphates stain with bismuth.     

Staining of intracellular deposits of uranium in cultured murine macrophages

In our studies of the health effects of internalized depleted uranium, we developed a simple and rapid light microscopic method to stain specifically intracellular uranium deposits. Using J774 cells, a mouse macrophage line, treated with uranyl nitrate and the pyridylazo dye 2-(5-bromo-2- pyridylazo)-5-diethylaminophenol, uranium uptake by the cells was followed. Specificity of the stain for uranium was accomplished by using masking agents to prevent the interaction of the stain with other metals. Prestaining wash consisting of a mixture of sodium citrate and ethylenediaminetetraacetic acid eliminated staining of metals other than uranium. The staining solution consisted of the pyridylazo dye in borate buffer along with a quaternary ammonium salt, ethylhexadecyldimethylammonium bromide, and the aforementioned sodium citrate/ethylene-diaminetetraacetic acid mixture. The buffer was essential for maintaining the pH within the optimum range of 8 to 12, and the quaternary ammonium salt prevented precipitation of the dye. Staining was conducted at room temperature and was complete in 30 min. Staining intensity correlated with both uranyl nitrate concentration and incubation time. Our method provides a simple procedure for detecting intracellular uranium deposits in macrophages.     

Alkaline bismuth solution as an en bloc stain for formaldehyde-glutaraldehyde potassium permanganate fixed fungal spores

An alkaline solution of bismuth subnitrate reacted well with the cell membranes and cell walls of formaldehyde-glutaraldehyde potassium permanganate fixed Alternaria spores, demonstrating them with greater contrast than in sections stained with uranyl acetate and lead citrate. Optimal fine structure of fungal spores was obtained by en bloc staining with alkaline bismuth solution after aldehyde and permanganate fixation. The contrast of the cell organelles and cell walls was high enough in sections cut after the alkaline bismuth en bloc stain for direct ultrastructural observation. Our results indicate that the alkaline bismuth stain is useful either as an en bloc or section stain for aldehyde and permanganate fixed fungal spores.