The osmium tetroxide-potassium ferrocyanide (OsFeCN) staining technique for electron microscopy: A critical evaluation using ciliates,algae, mosses,and higher plants

Summary The osmium tetroxide-potassium ferrocyanide (OsFeCN)-method has been applied to a variety (24 objects) of ciliates, algae, mosses, and higher plants in order to test its specificity. The results showed big variation. Depending on the object, either general staining of the membranes, or selective staining of certain membranes, and/or staining of non-membraneous components in secretory vesicles and cell walls was obtained. In some cases, ultrastructural preservation was better than in controls. It is concluded that this staining technique may be helpful in tracing certain membrane systems, but it seems by no means specific for calcium-sequestering membrane systems.With support of the Deutsche Forschungsgemeinschaft     

INTRAMITOCHONDRIAL FIBERS WITH DNA CHARACTERISTICS : I. Fixation and Electron Staining Reactions

Chick embryo mitochondria, studied with the electron microscope, show crista-free areas of low electron opacity. These areas are observable after fixation with osmium tetroxide, calcium permanganate, potassium permanganate, formaldehyde, acrolein, acrolein followed by osmium tetroxide, uranyl acetate followed by calcium permanganate, and acetic acid-alcohol. Staining of sections with lead hydroxide or uranyl acetate, or with both, resulted in an increased density of a fibrous material within these areas. The appearance of the fibrous structures varied with the fixative employed; after fixation with osmium tetroxide the material was clumped and bar-like (up to 400 A in diameter), whereas after treatment of osmium tetroxide-fixed tissues with uranyl acetate before dehydration the fibrous structures could be visualized as 15 to 30 A fibrils. Treatment with ethylenediaminetetraacetate (EDTA) in place of uranyl acetate coarsened the mitochondrial fibrils. After fixation with calcium permanganate or potassium permanganate, or a double fixation by uranyl acetate followed by calcium permanganate, the fibers appeared to have a pattern and ultrastructure similar to that observed after the osmium tetroxide-uranyl acetate technique, except that some of them had a slightly greater diameter (up to 50 A). Other fixatives did not preserve the fibers so well. The fibers appeared strongly clumped by formaldehyde fixation, and were difficult to identify after fixation with acrolein or acetic acid-alcohol. The staining of nucleic acid-containing structures by uranyl acetate and lead hydroxide was improved by treatment of osmium tetroxide-fixed sections with hydrogen peroxide, and the mitochondrial fibers also had an increased density in the electron beam after this procedure. The staining characteristics suggest the fibrous material of chick embryo mitochondria to be a nucleic acid-containing structure, and its variable appearance after different fixations parallels that previously reported, or described in this paper, for the nucleoplasm of bacteria and blue-green algae. The results, in addition to those described in the accompanying communication, indicate that these mitochondria contain DNA.     

A method for the chemical treatment of cells for the purpose of the subsequent study of the same cell culture preparation by light, scanning and transmission electron microscopy]

Cells cultured on transparent conductive substrates (glass coated with indium oxide) were fixed with aldehyde and osmium tetroxide and then treated with tannic acid, uranyl acetate and lead citrate. The same cell culture preparation could be sequentially studied by light microscopy (in water immersed condition), SEM (after dehydration and critical point drying) and TEM (after embedding in an epoxy resin). This method ensures the preservation of intact cell morphology, cell surface topography and intracellular structures. The treatments used render the cells conductivity and permit to carry out successfully SEM of uncoated cells cultured on conductive substrates. This method also provides a higher contrast of TEM images.     

PRESERVATION OF THE ULTRASTRUCTURE OF BACILLUS SUBTILIS BY CHEMICAL FIXATION AS VERIFIED BY FREEZE-ETCHING

The present study on the ultrastructure of Bacillus subtilis was undertaken in order to examine by means of the freeze-etching technique possible structural changes occurring during the chemical fixation procedure (Ryter-Kellenberger (R-K) fixation). Three stages were followed by freeze-etching, viz.: (a) fixation in osmium tetroxide, (b) fixation in osmium tetroxide and posttreatment with uranyl acetate, and (c) fixation in osmium tetroxide, posttreatment in uranyl acetate, and dehydration in a graded series of acetone. Preparations were made after each stage in the presence of 20% glycerol. Good preservation of ultrastructure was observed, after any of the three treatments, of the outer surface of the plasma membrane, and the inner surface of the plasma membrane. No alteration in fracturing properties could be observed. However, if we are to judge by the results of freeze-etching, any of the successive steps of the chemical fixation procedure achieve strong contrast between the nucleoplasmic region and the cytoplasm. Dependent on the quality of fixation, very delicately preserved DNA fibrils or strongly aggregated ones were seen. It appears that R-K fixation is capable of producing more or less distinctly visible changes in the native state of the nucleoplasm in young cells of B. subtilis.     

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.     

Preservation of alveolar type II pneumocyte lamellar bodies for electron microscopic studies.

Simultaneous fixation with glutaraldehyde and osmium tetroxide, followed by an uranyl acetate (UA) treatment before dehydration and embedding (Hirsch and Fedorko 1968) ensures a very good preservation of lamellar bodies (LB's) as well as of the cellular membranes in type II pneumocyte. The uranyl acetate treatment appeared to be the most efficient step of the procedure. The morphological aspect of lamellar bodies after such a preparation was similar to that observed after freeze-etching of lipid retaining methods. Moreover, the Hirsch-Fedorko procedure is very simple and can easily be used for routine ultrastructural and radioautographic studies. On the other hand, it appeared that the uranyl acetate phospholipid "complex" is very sensitive to the pH of chemical solutions used after sectioning. The "complex" is variously dissolved by alkaline solutions, photographic developers or stains. The best preservation of ultrastructure was obtained with neutral or acidic developers and acidic stains.     

Membrane associated qualitative differences in cell ultrastructure of chemically and high pressure cryofixed plant cells

Membrane contrast can sometimes be poor in biological samples after high pressure freezing (HPF) and freeze substitution (FS). The addition of water to the FS-medium has been shown to improve membrane contrast in animal tissue and yeast. In the present study we tested the effects of 1% and 5% water added to the FS-medium (2% osmium with 0.2% uranyl acetate in anhydrous acetone) on the quality and visibility of membranes in high pressure frozen leaf samples of Cucurbita pepo L. plants and compared them to chemically fixed cells (3% glutaraldehyde post-fixed with 1% osmium tetroxide). The addition of water to the FS-medium drastically decreased the amounts of well preserved cells and did not significantly improve the quality nor visibility of membranes. In samples that were freeze substituted in FS-media containing 1% and 5% water the width of thylakoid membranes was found to be significantly increased of about 20% and the perinuclear space was up to 76% wider in comparison to what was found in samples which were freeze substituted without water. No differences were found in the thickness of membranes between chemically and cryofixed cells that were freeze substituted in the FS-medium without water. Nevertheless, in chemically fixed cells the intrathylakoidal space was about 120% wider than in cryofixed cells that were freeze substituted with or without water. The present results demonstrate that the addition of water to the FS-medium does not improve membrane contrast but changes the width of thylakoid membranes and the perinuclear space in the present plant material. The addition of water to the FS-medium is therefore not as essential for improved membrane contrast in the investigated plant samples as it was observed in cells of animal tissues and yeast cells.     

An enhanced method for post-embedding immunocytochemical staining which preserves cell membranes.

We have devised a method for immunogold staining of unosmicated, plastic-embedded tissue which gives high levels of specific staining without scrificing cell ultrastructure. The key to this method is a combination of several standard techniques optimized to preserve cell membranes as well as antigen. Important conditions include (a) a combination primary fixative, (b) post-fixation with uranyl acetate to preserve membrane phospholipids, (c) dehydration with acetone to minimize extraction of phospholipids, (d) low-temperature embedding in LR Gold resin, and (e) use of osmium tetroxide to stain thin sections after immunogold labeling. We have developed this method specifically to localize the membrane receptor for immunoglobulin G in the jejunal epithelium of the neonatal rat. Ultra-thin sections of embedded tissue were stained with a monoclonal primary antibody and colloidal gold-labeled secondary antibody, followed by 2% osmium tetroxide and lead citrate. The receptor was resolved in the well-preserved network of tubules, endosomes, and other membrane compartments involved in immunoglobulin transport. In several other tissues processed by this method, cell ultrastructure resembled that seen after conventional osmium post-fixation and epoxy embedding. In addition to its usefulness in these studies, this general method should be applicable to many other immunocytochemical problems.     

Contrast-enhanced immunoelectron microscopy for Helicobacter pylori

Since a method of contrast enhancement for immunoelectron microscopy has not been available in bacteriology, the morphological localization of proteins of Helicobacter pylori is not well known. In this report, we established a method of contrast enhancement in immunoelectron microscopy in this organism. Immunostained ultrathin sections are stained with a mixture of alcian blue and osmium tetroxide prior to staining with uranyl acetate. This method of staining provided good contrast enhancement of the bacterial cell wall and membrane without any loss of immunolabeled gold particles on the ultrathin section.     

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.     

The structure of the endoplasmic reticulum revealed by osmium tetroxide-potassium ferricyanide staining

Postfixation of plant tissues with a mixture of osmium tetroxide and potassium ferricyanide (OsFeCN) yields a selective staining of the endoplasmic reticulum (ER) and nuclear envelope (NE). The other cytoplasmic organelles and inclusions are evident, but by comparison with the NE-ER they are weakly contrasted. Demarcation of the NE-ER results from the enhanced deposition of an electron-opaque reaction product on the inner leaflet of the membrane that extends into the cisternal space. The procedure thus renders the NE-ER readily apparent even when the elements are sectioned parallel to their surface and makes it possible to easily visualize their cellular pattern. Ultrastructural studies reveal with clarity tubular reticula and fenestrated lamellae that are extensively interconnected into one continuous membrane system. Problems with the OsFeCN procedure include the inability of the reagent to stain the NE-ER in all cells of a tissue, the occasional staining of non-ER such as dictyosomal cisternae and plastids, and the failure to selectively stain the NE-ER in protoplasts or single wall-less cells. Results obtained with OsFeCN are compared with other ER fixatives and stains including potassium permanganate and zinc iodide-osmium tetroxide. Despite its problems, under optimal circumstances OsFeCN is judged to be superior to other stain-fixatives for selectively contrasting the NE-ER compartment and is recommended generally for ultrastructural investigations.     

High-contrast en bloc staining of neuronal tissue for field emission scanning electron microscopy

Conventional heavy metal poststaining methods on thin sections lend contrast but often cause contamination. To avoid this problem, we tested several en bloc staining techniques to contrast tissue in serial sections mounted on solid substrates for examination by field emission scanning electron microscopy (FESEM). Because FESEM section imaging requires that specimens have higher contrast and greater electrical conductivity than transmission electron microscopy (TEM) samples, our technique uses osmium impregnation (OTO) to make the samples conductive while heavily staining membranes for segmentation studies. Combining this step with other classic heavy metal en bloc stains, including uranyl acetate (UA), lead aspartate, copper sulfate and lead citrate, produced clean, highly contrasted TEM and scanning electron microscopy (SEM) samples of insect, fish and mammalian nervous systems. This protocol takes 7-15 d to prepare resin-embedded tissue, cut sections and produce serial section images.     

Evaluation of freeze-substitution and conventional embedding protocols for routine electron microscopic processing of eubacteria.

Freeze-substitution and more conventional embedding protocols were evaluated for their accurate preservation of eubacterial ultrastructure. Radioisotopes were specifically incorporated into the RNA, DNA, peptidoglycan, and lipopolysaccharide of two isogenic derivatives of Escherichia coli K-12 as representative gram-negative eubacteria and into the RNA and peptidoglycan of Bacillus subtilis strains 168 and W23 as representative gram-positive eubacteria. Radiolabeled bacteria were processed for electron microscopy by conventional methods with glutaraldehyde fixation, osmium tetroxide postfixation, dehydration in either a graded acetone or ethanol series, and infiltration in either Spurr or Epon 812 resin. A second set of cells were simultaneously freeze-substituted by plunge-freezing in liquid propane, substituting in anhydrous acetone containing 2% (wt/vol) osmium tetroxide, and 2% (wt/vol) uranyl acetate, and infiltrating in Epon 812. Extraction of radiolabeled cell components was monitored by liquid scintillation counting at all stages of processing to indicate retention of cell labels. Electron microscopy was also used to visually confirm ultrastructural integrity. Radiolabeled nucleic acid and wall components were extracted by both methods. In conventionally embedded specimens, dehydration was particularly damaging, with ethanol-dehydrated cells losing significantly more radiolabeled material during dehydration and subsequent infiltration than acetone-treated cells. For freeze-substituted specimens, postsubstitution washes in acetone were the most deleterious step for gram-negative cells, while infiltration was more damaging for gram-positive cells. Autoradiographs of specimens collected during freeze-substitution were scanned with an optical densitometer to provide an indication of freezing damage; the majority of label lost from freeze-substituted cells was a result of poor freezing to approximately one-half of the cell population, thus accounting for the relatively high levels of radiolabel detected in the processing fluids. These experiments revealed that gram-positive and gram-negative cells respond differently to freezing; these differences are discussed with reference to wall structure. It was apparent that the cells frozen first (ie., the first to contact the cryogen) retained the highest percentage of all radioisotopes, and the highest level of cellular infrastructure, indicative of better preservation. The preservation of these select cells was far superior to that obtained by more conventional techniques.     

Ultrastructure of Cell Envelopes of Bacteria of the Bovine Rumen

Most of the bacteria found in rumen fluid samples taken from cows fed hay, or a concentrate diet, had cell walls of the gram-negative type. Most were intact, with only a small proportion of lysed cells, and many of the cells contained electron-translucent cytoplasmic deposits similar to the carbohydrate reserve material described in pure cultures of rumen organisms. All of the bacteria observed in these samples had an external "coat" layer outside the outer membrane when fixed in glutaraldehyde and osmium, stained with uranyl acetate and lead citrate, and examined as sectioned material. These coat layers varied from thin (ca. 8 nm) structures to very extensive fibrous systems, sometimes including concentric arrangements and radial fibers extending up to 1,200 nm from the cell. The thin-coat layers sometimes exhibited a rough periodicity. In all, 10 different types of coat layers were distinguishable on a morphological basis. It is proposed that these external coat layers have protective and adherence functions for the rumen bacteria in the environment.     

Improved Procedures for Electron Microscopic Visualization of the Cytoskeleton of Cultured Cells

We have developed an improved electron microscopic procedure appropriate for correlative light and electron microscopy of the cytoskeleton. The procedure is based on detergent extraction, chemical fixation, critical point drying, and platinum/carbon coating of cultured cells and the improvements consist of modifications which are minor individually but collectively of substantial impact. They are: inclusion of polyethylene glycol into the extraction medium; cell lysis at room temperature; fixation by sequential application of glutaraldehyde, tannic acid, and uranyl acetate; horizontal position of specimens during dehydration and drying; and uranyl acetate treatment during dehydration. As a result, we have obtained a greatly improved quality of electron microscopic images together with a high consistency of results. Long and straight actin filaments were clearly seen in stress fibers and newly formed lamellipodia. Their polarity was distinctly revealed by decoration with myosin subfragment 1. Depletion of actin from cytoskeletons by gelsolin treatment allowed for better visualization of myosin, intermediate filaments, and microtubules. Intermediate filaments exposed by this treatment exhibited numerous side projections in a hitherto unreported millipede-like appearance. The suggested procedure was compatible with immunogold labeling as demonstrated with an antibody to tubulin. Correlative light and electron microscopy of cells microinjected with a fluorescent derivative of myosin II was reliable and efficient, producing a close resemblance between the two kinds of images.     

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.     

Ultrastructure of sea urchin calcified tissues after high-pressure freezing and freeze substitution

The improvements brought by high-pressure freezing/freeze substitution fixation methods to the ultrastructural preservation of echinoderm mineralized tissues are investigated in developing pedicellariae and teeth of the echinoid Paracentrotus lividus. Three freeze substitution (FS) protocols were tested: one in the presence of osmium tetroxide, one in the presence of uranyl acetate, and the last in the presence of gallic acid. FS in the presence of osmium tetroxide significantly improved cell ultrastructure preservation and should especially be used for ultrastructural studies involving vesicles and the Golgi apparatus. With all protocols, multivesicular bodies, suggested to contain Ca(2+), were evident for the first time in skeleton-forming cells. FS in the presence of gallic acid allowed us to confirm the structured and insoluble character of a part of the organic matrix of mineralization in the calcification sites of the tooth, an observation which modifies the current understanding of biomineralization control in echinoderms.     

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.     

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.     

The use of osmium-thiocarbohydrazide-osmium (OTO) and ferrocyanide-reduced osmium methods to enhance membrane contrast and preservation in cultured cells

The preservation and contrast of membranous structures in cultured cells using various postfixation procedures prior to embedding have been investigated. These include routine OsO4, ferrocyanide-reduced OsO4, osmium-thiocarbohydrazide-osmium (OTO), and ferrocyanide-reduced osmium-thiocarbohydrazide-ferrocyanide-reduced osmium (R-OTO). With standard ethanol-Epon dehydration/embedding techniques, a dramatic improvement in both membrane contrast and preservation of bilayer membrane structure was achieved using preembedding OTO in cultured cells. R-OTO yielded similar enhanced preservation and contrast of membranes. Both of these methods also resulted in an increase in the contrast of diaminobenzidine reaction product from horseradish peroxidase activity, and of lipid droplets and lipoprotein particles. However, R-OTO did not cause the same increase in the density of proteinaceous elements as was seen with the OTO method. Ferrocyanide-reduced osmium alone showed significant advantages for quantitation of immunocytochemistry using ferritin labels with bismuth subnitrate counterstain. These methods should have general usefulness for the preservation of lipid-containing structures in cultured cells.