Methods for removing uranyl acetate precipitate from ultrathin sections.

Precipitate resulting from en bloc staining with uranyl acetate was removed by treating sections with 15% oxalic acid in 50% methanol for 30 minutes at 40 C. Precipitate resulting from poststaining sections with hot uranyl acetate was removed by rinsing sections in 0.25-0.50% aqueous oxalic acid for 10-15 seconds at room temperature. Rinsing sections for longer than 30 seconds removed uranyl precipitate and also destained the sections. These procedures did not damage the embedding medium or cellular detail.     

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.     

Staining Paraffin Sections with Protargol 6. Impregnation and Differentiation of Nerve Fibers in Adrenal Glands of Mammals

A series of experiments with protargol staining of nerve fibers in mammalian adrenal glands has yielded the following procedure: Fix-1-2 days in a mixture of formamide (Eastman Kodak Company) 10 cc, chloral hydrate 5 g., and 50% ethyl alcohol 90 cc. Wash, dehydrate and embed in paraffin. Cut sections about 15 and mount on slides. Remove the paraffin and run down to distilled water. Mordant 1-2 days in a 1% aqueous solution of thallous (or lead) nitrate at 56-60°C. Wash thru several changes of distilled water and impregnate in 1% aqueous protargol (Winthrop Chemical Company) at 37-40°C. for 1 to 2 days. Rinse quickly in distilled water and differentiate 7-15 seconds in a 0.1% aqueous solution of oxalic acid. Rinse thru several changes of distilled water for a total time of 0.5 to 1.0 rain. Reduce 3-5 rain, in Bodian's reducer: hydroquinone 1 g., sodium sulfite 5 g., distilled water 100 cc. Wash in running water 3-5 min. and tone 5-10 min. in a 0.2% gold chloride solution. Wash 0.5 min. or more and reduce in a 2% oxalic acid solution to which has been added strong formalin, 1 cc. per 100. (Caution. This last reduction is critical and over-reduction can spoil an otherwise good stain; 15-30 seconds usually suffices, and the sections should show only the beginning of darkening to a purplish or gray color.) Wash, fix in hypo, wash, dehydrate and cover.     

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.     

A Modified Nauta-Gygax Method for Human Brain and Spinal Cord

Relatively thick frozen sections of formalin-fixed human brains are treated subsequently with an equal-parts mixture of 1% oxalic acid and 1% hydroquinone for 30-60 min, 0.005% chromic acid for 10 min, 4% hydrobromic acid for 6 min, 1% phosphotungstic acid for 15 min, 0.05% potassium permanganate for 3-10 min, equal parts of 1% oxalic acid and 1% hydroquinone for 2-5 min. After thorough washing in distilled water, the sections are then soaked in 1.5% silver nitrate for 15-30 min, Laidlaw's ammoniacal silver carbonate for 2.5 min, and then reduced in the Nauta-Gygax reducer. The sections are washed and then passed through 1% sodium thiosulfate for 1-2 min; again washed, dehydrated, cleared and covered with synthetic resin.     

Simultaneous demonstration of glycogen and protein in glycosomes of cardiac tissue

Cardiac conduction fibers fixed either in glutaraldehyde and OsO4 or treated additionally en bloc with uranyl acetate were studied in order to demonstrate the structure of glycosomes (protein-glycogen complex). Sections were stained histochemically by periodic acid-thiosemicarbazide-silver proteinate (PA--TSC--SP) for glycogen followed by uranyl acetate and lead citrate (U-Pb) for protein. In control sections periodic acid was replaced by hydrogen peroxide (H2O2). Glycogen appeared in all sections stained by PA-TSC-SP. Protein was poorly contrasted in periodic acid treated histochemical sections taken from fixed in glutaraldehyde and OsO4. Simultaneous staining of glycogen and protein was achieved in sections of tissue treated en bloc with uranyl acetate. This treatment revealed two classes of glycosomes: 1) glycosomes deposited freely in the cytoplasm whose structure was disintegrated after treatment with uranyl acetate: 2) glycosomes associated with other cellular structures that remained intact. Staining of glycogen and protein in the same section demonstrated for the first time the structure of intact glycosomes.     

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.     

Synaptology of the claustrum in the rat

A great deal of information is available on the morphology of the claustrum in various animal species, as well as on its neuronal distribution and relationships with the cerebral cortex and other nuclei. However, no research has been performed on synaptic organization. Here we report an ultrastructural study performed on 7 male albino rats of the Wistar strain weighing 270-310 g. Five rats were sacrificed by prolonging general anesthesia with diethyl ether until death. Three of these rats were secured to the stereotaxic atlas coordinates of Paxinos and Watson (1982); the claustrum area was marked by injecting 1 microliter of a 10% Evans Blue solution into the nucleus. The brain was then removed from the skull, cut into 2-3 mm thick coronal sections, and tissue samples taken from the area immediately adjacent to the marked area were immersed in 2% OsO4 buffered with 2% potassium dichromate containing 0.2% CaCl2 at pH 7.7 (Gobel, 1968). After dehydration they were embedded in Durcupan and the ultrafine sections were stained with uranyl acetate and lead citrate and observed with either a Zeiss 9S2 or a Hitachi H 800 electron microscope. The samples from two other rats, taken with the stereotaxic techniques described, were fixed for 12 h in 0.6 potassium permanganate solution buffered with veronal-acetate at pH 7.4 (Luft, 1956). After processing for electron microscopy, a portion of the sections were used without any contrast medium and the remainder were stained with uranyl acetate and lead citrate.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Selective Staining of Neurosecretory Material in Semithin Epoxy Sections by Gomori's Aldehyde Fuchsin

The epoxy resin was removed from semithin (1 μm) sections by immersing them for 30 sec in sodium methoxide (Mayor et al., J. Biophys. Biochem. Cytol., 9: 909-10, 1961) and then processed as follows: (1) left for 1-3 hr at 60 C in a mixture of formalin, 25 ml; glacial acetic acid, 5 ml; CrO₃, 3 gm; and distilled water, 75 ml: (2) oxidized 10 min in a 1:1:6 v/v mixture of 2.5% KMnO₄, 5% H₂SO₄ and distilled water: (3) bleached in 1% oxalic acid, and (4) stained for 15 min in aldehyde fuchsin, 0.125% in 70% alcohol, or in a 1% aqueous solution of toluidine blue. The neurosecretory material is selectively stained.     

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)     

Masking of pleomorphic glycogen sites by methanolic uranyl acetate.

Rat liver tissue was fixed in 2.5% glutaraldehyde buffered with cacodylic acid (pH 7.3) for 2 hr, washed twice in buffer, and postfixed in 2% osmium tetroxide at 4 C for 1 hr. The tissue then was dehydrated, infiltrated with and embedded in Epon by routine procedures. The ultrathin sections from this tissue, when stained with spectroscopic grade methanol saturated with uranyl acetate (SMUA) for 1 min followed by aqueous lead citrate (PbCi) (Reynolds 1963) for 5 min at room temperature, showed a uniform staining of all major cellular components except glycogen. The SMUA appeared to be specific for ribonuceloprotein granules, rendering them more prominent in the cytoplasm due to the lack of glycogen staining. The question of glycogen removal from the sections due to SMUA treatment was evulated using various extractions and staining methods. It appeared that SMUA pretreatment alters the subsequent binding ability of lead salts, resulting in lack of glycogen staining, although it does not remove the glycogen from the sections.     

Masking of Pleomorphic Glycogen Sites by Methanolic Uranyl Acetate

Rat liver tissue was fixed in 2.5% glutaraldehyde buffered with cacodylic acid (pH 7.3) for 2 hr, washed twice in buffer, and postfixed in 2% osmium tetroxide at 4 C for 1 hr. The tissue then was dehydrated, infiltrated with and embedded in Epon by routine proocdures. The ultra thin sections from this tissue, when stained with spectroscopic grade methanol saturated with uranyl acetate (SMUA) for 1 min followed by aqueous lead citrate (PbCi) (Reynolds 1963) for 5 min at room temperature, showed a uniform staining of all major allular components ercept glycogen. The SMUA appeared to be specific for ribonucleoprotein granules, rendering them more prominent in the cytoplasm due to the lack of glycogen staining. The question of glycogen removal from the sections due to SMUA treatment was evaluated using various extractions and staining methods. It appeared that SMUA pretreatment alters the subsequent binding ability of lead salts, resulting in lack of glycogen staining, although it does not remove the glycogen from the sections.     

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.     

Camwood (Baphia nitida) Extract as a Histological Stain for Interglobular Dentine, Striated Muscle, and Counterstaining

The shavings of the dried heartwood of the tree Baphia nitida are ground to a fine powder, and 6 gm of the powder are extracted in 100 ml absolute ethanol at 27-30 for 6-24 hr. The extract is filtered with Whatman No. 1 paper and stored in a screw-capped bottle. For staining the interglobular dentine of nondecalcified sections of formlin-fixed teeth, sawed cross sections 20-30 μ thick were dehydrated in ethanol and stained in the undiluted extract for 6-12 hr at room temperature. The interglobular dentine was stained a bright golden brown on a pale brown background. For staining striated muscle, the extract was diluted 1:1 with distilled water and filtered. After mordanting formalin-fixed paraffin sections with 0.25% KMnO₄ for 5 min, and bleaching with 5% oxalic acid for 10 min, they were washed in water and stained for 2-24 hr at room temperature. The striations were stained light to deep golden brown. For use as a counterstain, a 1:6 dilution of the original extract was required. When applied after haematoxylin for 15-30 min, it stained tissue components in varying shades of golden brown with distribution comparable to that produced by 1% eosin.     

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.     

A simple method for the liquid scintillation counting of precipitated protein from red blood cells

A method for the liquid scintillation counting of precipitated protein from red cells in 0.1–1.0 ml of blood is described. Precipitate is incubated for 0.5 hr at 100°C with equal volumes of acetic acid, ethyl acetate, and hydrogen peroxide; an equal volume of hydrochlorie acid is then added, followed by a toluene/Triton X-100 scintillation mixture containing primary and secondary scintillators. Maximum counting efficiencies with precipitate from 0.2 ml of blood were 90% for ¹⁴C and 35% for ³H. Recovery of labeled amino acid was not less than 90%. Chemiluminescence decayed to not more than 15 cpm above background in 45 min.     

Improved nuclear staining with mordant blue 3 as a hematoxylin substitute.

For progressive staining 1 g mordant blue 3, 0.5 g iron a alum and 10 ml hydrochloric acid are combined to make 1 liter with distlled water. Paraffin sections are stained 5 minutes blued in 0.5% sodium acetate for 30 seconds and counterstained with eosin. For regressive staining, 1 g dye, 9 g iron alum and 50 ml acetic acid are combined to make 1 liter with distilled water. Staining time is 5 minutes followed by differentiation in 1% acid alcohol and blueing in 0.5% sodium acetate. Counterstain with eosin. In both cases results very closely results very resemble a good hematoxylin and eosin.