Electron dense artefactual deposits in tissue sections: the role of ethanol, uranyl acetate and phosphate buffer.

The occurrence of electron dense deposits in sections of aldehyde-fixed tissue prepared for transmission electron microscopy has been attributed to a number of conflicting factors. In an attempt to clarify this, the precipitating effect of different combinations of phosphate or cacodylate buffer, glutaraldehyde, ethanol and uranyl acetate was investigated in test tubes. As a preliminary investigation the combination of phosphate buffer, ethanol and uranyl acetate was investigated in heart and kidney tissue fixed in glutaraldehyde with or without postosmication. The essential factors in the formation of electron dense deposits in these tissues appear to be phosphate buffer, ethanol, and uranyl acetate, although glutaraldehyde may contribute in some way. The nature and intensity of the deposits seem to vary with the sequence of combination of these factors. Osmium did not appear to be an essential factor in the reaction since deposits were observed in both osmicated and unosmicated tissue. To avoid such deposits, a postosmication distilled water wash for 20 to 30 min followed by en bloc staining with aqueous uranyl acetate is advised if phosphate buffer is used as a fixative vehicle or buffer wash after the primary fixative.     

Calcium binding to intestinal membranes

Flame photometry reveals that glutaraldehyde and buffer solutions in routine use for electron microscopy contain varying amounts of calcium. The presence of electron-opaque deposits adjacent to membranes in a variety of tissues can be correlated with the presence of calcium in the fixative. In insect intestine (midgut), deposits occur adjacent to apical and lateral plasma membranes. The deposits are particularly evident in tissues fixed in glutaraldehyde without postosmication. They are also observed in osmicated tissue if calcium is added to wash and osmium solutions. Deposits are absent when calcium-free fixatives are used, but are present when traces of CaCl₂ (as low as 5 x 10^-5 M) are added. The deposits occur at regular intervals along junctional membranes, providing images strikingly similar to those obtained by other workers who have used pyroantimonate in an effort to localize sodium. Other divalent cations (Mg⁺⁺, Sr⁺⁺, Ba⁺⁺, Mn⁺⁺, Fe⁺⁺) appear to substitute for calcium, while sodium, potassium, lanthanum, and mercury do not. After postfixing with osmium with calcium added, the deposits can be resolved as patches along the inner leaflet of apical and lateral plasma membranes. The dense regions may thus localize membrane constituents that bind calcium. The results are discussed in relation to the role of calcium in control of cell-to-cell communication, intestinal calcium uptake, and the pyroantimonate technique for ion localization.     

Use of Hot Formaldehyde Fixative in Processing Plant-Parasitic Nematodes for Electron Microscopy

A preparative technique is formulated for processing plant-parasitic nematodes of the order Tylenchida for electron microscopy. A population of Dolichodorus heterocephalus is used as test objects. One and a half grams of paraformaldehyde are dissolved in 25 ml of water at 60 C. Five drops of 1 N sodium hydroxide are added to clear the solution, which is then cooled to room temperature. Two and a half milliliters of 25% glutaraldehyde are added with 23 ml 0.1 M phosphate buffer, pH 7.3, and 0.2 M with respect to sucrose. The final solution contains 3% formaldehyde and 1% glutaraldehyde and is pH 7.2. It is heated to 70 C, poured over specimens, and allowed to cool to 4 C in 2 hr. The nematodes are then incised in a fixative containing 2% glutaraldehyde and 5% dimethyl sulfoxide at 4 C for 16-24 br. Five milliliters of 25% glutaraldehyde and 2.5 ml of dimethyl sulfoxide are combined in 17.5 ml of water. Twenty-five milliliters of phosphate buffer (supplemented as above) are added. The final pH is 7.2. The glutaraldehyde, aided by dimethyl sulfoxide, uniformly and permanently fixes the nematode tissues. The specimens are embedded in agar. Following a 30-min buffer wash (4 C) they are postfixed in buffered 2% osmium tetroside for 2 hr at room temperature, washed, and dehydrated through an ethanol series and two acetone baths. Dehydration includes a 2-hr stop in 75% ethanol containing 2% uranyl acetate. After embedding in Spurr's epoxy resin, specimens are sectioned and poststained in 0.5% aqueous uranyl acetate for 6 min and saturated aqueous lead citrate 3-4 min.

This technique reduces killing time to less than 2 sec, straightens specimens for easier orientation, and eliminates the typically high internal pressure of nematodes which causes displacement of internal structures observed with other fixation techniques.     

Use of nitrogen mustard N-oxide for the fixation of electron microscopic tissues

Summary Nitrogen mustard N-oxide was tried for the fixation of tissue for electron microscopy. A fixative consisting of 1% nitrogen mustard N-oxide, 1% glutaraldehyde and 1% paraformaldehyde buffered at pH 7.4 followed by 1% O_sO₄ buffered at pH 7.4 was found useful for the tissues examined: thyroid, anterior pituitary, adrenal gland and oviduct of mice.If the tissues are fixed and the sections are stained with uranyl acetate and lead acetate doubly, the follicle colloid, colloid droplets, and secretory granules containing thyroglobulin in the thyroid become higher in electron density. The cisterna of the maturing face of the Golgi apparatus, secretory granules, ribosomes, nucleolus and chromatin in the cells examined are extremely electron dense. Tubular elements of smooth endoplasmic reticulum in the adrenal cortical cell and microtubules in all the cells examined are also well preserved. The fixative containing nitrogen mustard N-oxide is useful also for cytochemistry. Using tissue fixed by this method and stained en bloc by uranyl acetate, the noradrenaline and adrenaline cells in the adrenal medulla are clearly distinguished by light microscopy.This study was supported by a grant from the Japan Educational Ministry     

An Improved Technique for Dissociating Hepatocytes from Fixed Mouse Liver for Cytochemistry

A refined version of a method described previously for dissociating hepatocytes from fixed liver is described. The objective was to develop a procedure that would dispense with the postosmication of previously fixed tissue. In the new procedure fixed liver blocks are wrapped with a quadruple layer of nylon cloth, and, by squeezing them in a buffer solution, individually dissociated cells pass through the cloth without significant damage. The procedure makes it possible to dissociate liver tissue fixed with modified Karnovsky's fixative, Zamboni's fixative or cacodylate buffered glutaraldehyde. The subsequent compatibility of the single cells obtained with many cytochemical procedures has been confirmed.     

An improved technique for dissociating hepatocytes from fixed mouse liver for cytochemistry

A refined version of a method described previously for dissociating hepatocytes from fixed liver is described. The objective was to develop a procedure that would dispense with the postosmication of previously fixed tissue. In the new procedure fixed liver blocks are wrapped with a quadruple layer of nylon cloth, and, by squeezing them in a buffer solution, individually dissociated cells pass through the cloth without significant damage. The procedure makes it possible to dissociate liver tissue fixed with modified Karnovsky's fixative, Zamboni's fixative or cacodylate buffered glutaraldehyde. The subsequent compatibility of the single cells obtained with many cytochemical procedures has been confirmed.     

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.     

Preservation of fine Structures in Yeast by Fixation in a Dimethyl Sulfoxide-Acrolein-Glutaraldehyde Solution

The primary fixative containing 2% acrolein, 2% glutaraldehyde in 50% aqueous dimethyl sulfoxide (DMSO) buffered at pH 7.4, was applied for 7 hr in the cold. After a short wash in 0.02 M s-collidine buffer, pH 7.4, containing 0.2 M sucrose and 0.001 M CaCl₂, the yeast cells were postfixed in 3% OsO₄ at pH 4.0 (veronal acetate buffer). This method preserves many cytoplasmic features such as lipid deposits and ribosomes which are usually destroyed by permanganate fixation. DMSO apparently acts as a permeating agent allowing maximum penetration of the cell wall by the fixative without disrupting cellular fine structure     

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.     

Glycosomes (protein-glycogen complex) in the canine heart. Ultrastructure, histochemistry and changes induced by acidic treatment.

Cardiac conducting fibers were selected from two dogs defined as A and B. The specimens differed in the reaction of their electron dense granules, commonly referred to as glycogen, to the treatment en bloc with uranyl acetate. Material was fixed in glutaraldehyde and OsO4. Blocks were processed either conventionally or immersed in uranyl acetate before dehydration. Sections were examined unsatined, stained with U and/or Pb or with a histochemical technique (PA-TSC-SP) specific for glycogen. Electron dense granules have affinity to Os, U and Pb which suggests ionic reactions specific for protein but improbable for glycogen. Large granules in A turned into pale ghosts and small granules in B disappeared after treatment en bloc with uranyl acetate. PA-TSC-SP in conventional samples showed glycogen particles arranged into aggregates corresponding in size to the electron dense granules. Treatment en bloc slightly affected glycogen aggregates in A and resulted in a formation of large clumps of glycogen particles in B. It was concluded that the electron dense granules represented protein bound to glycogen in the organelles called glycosomes. Acidic action of uranyl acetate removed protein from glycosomes. The degree of this removal depended on the amount of protein present in glycosomes in the moment of fixation.     

Extraction of osmium-containing lipids by section staining for TEM

Postfixation with osmium-ferrocyanide or OSO4 renders lipid droplets in rat liver and kidney homogeneously electron dense without additional section staining. In sections of the same block that have been single stained by uranyl acetate or lead citrate, lipid droplets show a more electron translucent center surrounded by a dense rim. In sections double stained with uranyl acetate and lead citrate, lipid droplets frequently appear as empty vacuoles, from which the electron dense content has been completely extracted.     

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.     

Effect of chemical fixatives on accurate preservation of Escherichia coli and Bacillus subtilis structure in cells prepared by freeze-substitution.

Five chemical fixatives were evaluated for their ability to accurately preserve bacterial ultrastructure during freeze-substitution of select Escherichia coli and Bacillus subtilis strains. Radioisotopes were specifically incorporated into the peptidoglycan, lipopolysaccharide, and nucleic acids of E. coli SFK11 and W7 and into the peptidoglycan and RNA of B. subtilis 168 and W23. The ease of extraction of radiolabels, as assessed by liquid scintillation counting during all stages of processing for freeze-substitution, was used as an indicator of cell structural integrity and retention of cellular chemical composition. Subsequent visual examination by electron microscopy was used to confirm ultrastructural conformation. The fixatives used were: 2% (wt/vol) osmium tetroxide and 2% (wt/vol) uranyl acetate; 2% (vol/vol) glutaraldehyde and 2% (wt/vol) uranyl acetate; 2% (vol/vol) acrolein and 2% (wt/vol) uranyl acetate; 2% (wt/vol) gallic acid; and 2% (wt/vol) uranyl acetate. All fixatives were prepared in a substitution solvent of anhydrous acetone. Extraction of cellular constituents depended on the chemical fixative used. A combination of 2% osmium tetroxide-2% uranyl acetate or 2% gallic acid alone resulted in optimum fixation as ascertained by least extraction of radiolabels. In both gram-positive and gram-negative organisms, high levels of radiolabel were detected in the processing fluids in which 2% acrolein-2% uranyl acetate, 2% glutaraldehyde-2% uranyl acetate, or 2% uranyl acetate alone were used as fixatives. Ultrastructural variations were observed in cells freeze-substituted in the presence of different chemical fixatives. We recommend the use of osmium tetroxide and uranyl acetate in acetone for routine freeze-substitution of eubacteria, while gallic acid is recommended for use when microanalytical processing necessitates the omission of osmium.     

Cyto- and histochemical demonstration of lignins in plant cell walls: an evaluation of the chlorine water/ethanolamine-silver nitrate method of Coppick and Fowler

Summary The chlorine water/ethanolamine-silver nitrate method introduced by Coppick and Fowler for the detection of lignins was evaluated for cyto- and histochemical work using different reagents and fixatives for specimens embedded in epoxy resin. Fixation schedules tested included ethanol, glutaraldehyde, and glutaraldehyde followed by O_sO₄ as a post-fixative. Chlorine water, sodium hypochlorite, and calcium hypochlorite were the oxidising agents evaluated for their efficacy as part of the Coppick and Fowler procedure. The Coppick and Fowler method was tested against stem woody tissue ofLophomyrtus obcordata, and haustorial xylem tissue of the sucker of its attached dwarf mistletoeKorthalsella lindsayi. The presence of lignins in walls of these cells was indicated in thin sections for transmission electron microscopy by fine electron-dense deposits. Post-staining thin sections did not affect the lignin reaction, but tended to mask its effect due to increased wall contrast. In histological preparations lignified walls stained orange/brown. Counter-staining in methylene blue/azur B caused lignified walls to appear dark green/brown and non-lignified walls blue. Fixation in either ethanol or glutaraldehyde produced identical staining for lignins. Penetration by chlorine water was sometimes irregular, more so with glutaraldehyde fixation, with parts of tissues consequently not responding to the lignin reaction. Post-fixation in osmium tetroxide following primary fixation in glutaraldehyde slightly improved penetration of chlorine water. However, osmium caused greater amounts of extraneous stain deposits compared with other fixative regimes. Chlorine water was confirmed as the most effective oxidising agent for reacting with groups in lignins to produce reducing residues in the Coppick and Fowler method. Sodium hypochlorite caused no reaction. Calcium hypochlorite exhibited limited oxidative capacity resulting in slight staining for lignins. The Coppick and Fowler procedure was concluded to be a suitable method for demonstrating lignins in cyto- and histochemical preparations using material fixed in either ethanol or glutaraldehyde, and with embedding in epoxy resin.     

Factors affecting lead capture methods for the fine localization of rat lung acid phosphatase

Synopsis Gomori's lead capture method for acid phosphatase localization was adapted for the electron microscope by Holt & Hicks (1961a). The method gave good results in rat liver, but poor tissue preservation with no reaction product in rat lung, and was, therefore, investigated in order to find the optimum conditions for the ultrastructural localization of rat lung acid phosphatase. The conditions investigated included the use of glutaraldehyde or depolymerized paraformaldehyde as the fixative, with and without dimethylsulphoxide; the effect of freezing the tissue; the pH of the incubation medium; and the use of glycerophosphate, naphthol AS-BI phosphate or -naphthyl phosphate as substrates. Improved preservation of ultrastructure with increased yield of reaction product was obtained by prefixing lung in glutaraldehyde containing 10% dimethylsulphoxide, freezing the tissue and incubating at pH 5.7 with -naphthyl phosphate. Tissue preservation was acceptable and dense deposits of reaction product occurred in lysosomal elements of all the alveolar cells and especially in macrophages. Deposits were also found closely associated with the lamellae of the inclusion bodies of Type II cells.     

Identification of pancreatic glucagon cells in the cartilaginous fish Scyliorhinus canicula by ultrastructural immunocytochemistry

The ultrastructural localization of glucagon in the presence of Scyliorhinus canicula was investigated. We used a post-embedding immunoelectron microscopy method on pancreatic samples fixed in glutaraldehyde and osmicated before embedding. Contrasting with uranyl acetate and lead citrate was also performed after immunolabelling, but best results were obtained with uranyl acetate only. Glucagon-like immunoreactivity was located in round granules (300-600 nm) surrounded by a limiting membrane. The matrix varied in electron density and exhibited a dense core surrounded by a less dense mantle. The granules were seen in two different cell types, which differed in the electron density of their cytoplasm. Glucagon-immunoreactive cells were the largest pancreatic cells types and were often localized near somatostatin-containing cells.     

Changes in red blood cell volume on fixation in glutaraldehyde solutions

Summary Light scattering (nephelometry) was used to determine directly the change in volume of red blood cells immersed in a variety of buffer and fixative solutions. Cells immersed in saline or phosphate buffer solutions showed a change in volume that reflected the osmolarity of the solution, shrinkage taking place in hypertonic solutions and swelling and haemolysis occurring in strongly hypotonic solutions. On the other hand, while there was considerable shrinkage in hypertonic glutaraldehyde solutions, swelling was more restricted and haemolysis was prevented in the weaker glutaraldehyde solutions. Thus, while glutaraldehyde exerts a definite osmotic effect on cells in fixative solutions, the magnitude of this effect seems to be limited by its direct action as a fixative.     

Ultrastructural and ultrahistochemical studies on ventricular endocardial cells in teleosts (Pisces)

The ultrastructure of the ventricular endocardial cells in 17 bony-fish species representing eight families, is described. In species of Characidae, Cobitidae, Cyprinidae, and Gyrinocheilidae these cells are flat (1–2 µm at nucleus) and contain numerous ribosomes, some few bristle-coated vesicles (BCV) and small (0.243 pm) electron dense inclusion bodies. However, in species of Cichlidae, Gadidae, and Poeciliidae most endocardial cells appear relatively thicker (2–5 µm at nucleus) and contain numerous BCV, tubules of agranular endoplasmic reticulum, and large (0.5-1.5 µm) moderately electron dense bodies (MDB). In the MDB occur a number of small (20–150 nm) electron dense granules. Within the family Anabantidae, most endocardial cells seem to be of the first type in Colisa laliu and Trichogaster leeri. whereas in Helosioma iemmincki there are numerous cells of the second type. When glutaraldehyde/tannic acid fixed heart tissue of Pollachius virens is treated with ferrous chloride, ferric chloride, or osmium tetroxide, and grid stained by uranyl and lead solutions, damaged endocardial cells appear highly electron dense, whereas undamaged ones are electron lucent. Further, when glutaraldehyde fixed tissue is treated with osmium tetroxide/potassium ferrocyanide the subendocardial space is filled by a highly electron dense material. The methods described in this study make it possible to distinguish between those endocardial vacuoles having structural contact with the cell membrane, and those lacking such contact, and also to determine whether the lumen of the former is continuous with the subendocardial space, or with the intertrabecular lumen.     

Impact of glutaraldehyde versus glutaraldehyde-formaldehyde fixative on cell organization in fish corneal epithelium

The purpose of this study was to examine the impact of a low osmolality glutaraldehyde fixative and a high osmolality glutaraldehyde-formaldehyde fixative on the structural organization of a tissue that could be exposed to low and high osmolality environments. The corneas of freshwater trout were prepared for transmission and scanning electron microscopy using either a fixative of 2% glutaraldehyde in 60 mM cacodylate buffer (pH 7.8, 260 mOsm/l) or a fixative prepared by adding 2.5% glutaraldehyde to a solution of 1% formaldehyde and buffering the solution with 0.1 M cacodylate (pH 7.6, 850 mOsm/l; Karnovsky-type fixative). The corneal epithelial cell layer thickness was greater after glutaraldehyde compared to glutaraldehyde-formaldehyde fixation (67 vs 55 mum), as was the thickness of the superficial cells (5.1 vs 3.4 mum) and basal cells (43 vs 38 mum). The intermediate (wing) cells of the epithelium were, however, less thick after glutaraldehyde fixation (15 vs 18 mum). The width of the squamous, intermediate and basal cells was greater following glutaraldehyde fixation with the effect being greatest in the superficial layers and insignificant at the level of the basal cells. The results show that chemical fixatives with extremes of osmolality cannot only produce different cell sizes in a tissue but also determine the overall organization of the cells in a positional-dependent fashion.     

The use of methyl green-pyronin staining after glutaraldehyde fixation and paraffin or araldite embedding.

Methyl green-pyronin staining has been used for localization of RNA and DNA in chick and mouse embryonic tissues and in insect larval salivary glands. Glutaraldehyde or tricholoracetic acid-lanthanum acetate (TCA-LA) was used as fixative and paraffin wax or Araldite was used as embedding medium. For good results the following are specially desirable: fixation with 2.5% glutaraldehyde, dehydration in alcohols for short time, and the use of fresh staining solutions. After TCA-LA fixation the final results are much less specific. The digestion with RNAse appears essential for the detection of RNA because pyronin does not seem to be entirely specific to RNA. The results show that glutaraldehyde a common fixative for electron microscopic work, is particularly suitable fixative for light microscopic cytochemical investigations if followed by methyl green-pyronin staining; furthermore, methyl green-pyronin staining after glutaraldehyde fixation can be carried out on Araldite sections.