Staining the Nucleus in Yeasts

Yeast cells kept young by repeated subculturing were centrifuged, washed twice in distilled water and smeared on slides coated with a little egg albumen. The cells were treated with 0.002 M 8-hydroxyquinoline for 1 hr, fixed first in OsO, vapour for 30 sec and then in chloroform for 30 sec. The slides were passed through descending grades of alcohol, washed in distilled water, then immersed in 0.17 M NaCl solution for 2 hr. at 57°C. They were again washed in distilled water and later hydrolysed in 1 N HCl at 60°C for 5-7 min. This was followed by washing in distilled water and in buffer. The slides were then kept for 3 hr in Giemsa stain comprising 96 ml of phosphate buffer of pH 7.0 and 4 ml of the stain. After dehydration, mounting was done in balsam. Nuclei were brightly stained and well differentiated; centrosomes were clear, and the process of nuclear division and movement to daughter cells could be studied. Pretreatment with 8-hydroxyquinoline increased the viscosity of the cytoplasm, while NaCl treatment and acid hydrolysis led to the complete removal of ribonucleic acid and basophilic material. A selective staining of chromatin was thus achieved. Structures resembling chromosomes could be seen when fixed and stained cells were squashed, soon after the removal of the slides from the stain, under a cover glass by applying uniform pressure with a rubber stopper. Fixation in osmic acid vapor and chloroform followed by acid hydrolysis and staining in leucobasic fuchsin also helps to obtain bright staining of the nucleus; however, the preparations are inferior to those obtained after 8-hydroxyquinoline, NaCl treatment and Giemsa staining.     

Straight Oso4 versus Glutaraldehyde-Oso4 In Sequence as Fixatives for the Granular Vesicles in Sympathetic Axons of the Rat Pineal Body

Pineal bodies were removed immediately after death from 6 rats: representing both sexes, and adult and 21-day postnatal ages; cut into 2 or 3 pieces, and subjected to experimental fixations at pH 7.3, 0-4 C as follows: 1-2 hr in 1% OsO₄, with veronal-acetate buffer of phosphate buffer; 3-4 hr in 3% or 6% glutaraldehyde in 0.1 M or 0.2 M phosphate buffer, with or without 1% sucrose. Specimens from OsO₄ were dehydrated, and embedded in epoxy resin; those from glutaraldehyde were allowed to soak in buffer for 12-16 hr, then transferred to 1% OsO₄ at 0-4 C for 2 hr, and embedded in the same manner as the ones fixed directly in OsO₄. Representative electron micrographs of postganglionic sympathetic endings were studied for the morphology and frequency of granular vesicles. No consistent difference was shown between vesicles fixed in OsO₄ buffered by phosphate or by veronal-acetate, nor was there any effect caused by the different concentrations used for the glutaraldehyde solution; however, vesicles fixed by the glutaraldehyde-OsO₄ sequence showed an enhancement in the graininess of their membranes, were slightly larger, and had a much larger dense core than those fixed by OsO₄ alone. After glutaraldehyde-OsO₄, granular vesicles showed a frequency of 81%, whereas after direct fixation in OsO₄, only 40% without significant change their number per unit area. Therefore, glutaraldehyde-OsO₄ seems to be more effective than straight OsO₄ for the demonstration of granular vesicles in the autonomic nervous system.     

Collagenase Digestion for Distinguishing Neural from Reticular Fibres in Silver Stains

Fresh frozen sections of liver and duck salt gland, 20 μ thick were attached to slides and immersed for 20 min in Carnoy's 6:3:1 fixative; washed 3 times with 0.9% NaCl; placed in M/15 phosphate buffer, pH 7.0 for 20 min; then incubated for 5 hr at 37 C in a 0.1% solution of collagenase (Koch-Light Laboratories) in the phosphate buffer. After washing in 0.9% NaCl the slides were immersed for at least 24 hr in 4% formaldehyde (10% formol-saline). Slides were examined for morphological detail after haematoxylin and eosin staining, for nerve fibres after silver impregnation, and for connective tissue fibres. Attempts to use papain and pepsin digestion on sections after similar fixation were not successful, as much of the tissue was destroyed.     

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.     

Purification of 120-Kilodalton Phytochrome from Oryza Sativa L

The procedures of Grimm and Rüdiger for the purification of 120 kDa phytochrome from oat seedlings were modified to isolate native phytochrome from etiolated rice (Oryza sativa L. subsp, japonica var. nongken 58) seedlings. Approximately l kg of 6d old seedlings (the first 2 days at 33℃, the last 4 days at 27 ℃ in darkness) were frozen in liquid nitrogen and then homogenized in a modified Waring blendor with an extraction buffer, at final pH 8.45 (4 ℃). After polyethylenimine precipitation, phytochrome in extract was converted to Pfr by irradiation of the resulting supernatant for 10 min with red light. The step of ammonium sulfate precipitation was followed by resuspending of resultant pellet in buffer B with the ratio of 10 ml per phytochrome unit. The pellet precipitated with ammonium sulfate at 42% saturation from combined phytochrome cont ning fractions after hydroxyapatite chromatography was washed with 10 mmol/l phosphate buffer in 0.8 ml instead of 0.65 ml per phytochrome unit. Then it was washed successively with 200 mmol/l and 100 mmol/1 phosphate buffer (0.85 ml per phytochrome unit). Native phytochrome (120 kDa) in 12% yield was dissolved in 2 mmol/l EHPES buffer (2.2 ml per phytochrome unit, pH 7.8, containing 5 mmol/l EDTA and 14 mmol/l 2-mercaptoethanol) was proved to be pure in SDS- polyacrylamide electrophoresis and showed typical absorption spectrum as that of native oat phytochrome.     

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.     

Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

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.     

Automated method for the determination of a new matrix metalloproteinase inhibitor in ovine plasma and serum by coupling of restricted access material for on-line sample clean-up to liquid chromatography

A fully automated liquid chromatographic method was developed for the determination of Ro 28-2653, a new synthetic inhibitor of matrix metalloproteinases (MMPs), in ovine serum and plasma. The method was based on the coupling of a pre-column packed with restricted access material, namely LiChrospher RP-8 ADS (alkyl diol silica), for sample clean-up to an analytical column containing octyl silica stationary phase. One hundred microl of biological sample, to which 2-propanol was automatically added, were injected onto the ADS pre-column, which was then washed with a washing liquid consisting of a mixture of 25 mM phosphate buffer (pH 7.0) and acetonitrile (90:10; v/v) for 10 min. By rotation of the switching valve, the analyte was then eluted in the back-flush mode with the LC mobile phase composed of a mixture of acetonitrile and 25 mM phosphate buffer (pH 7.0) (57:43; v/v). The UV detection was performed at 395 nm. The main parameters likely to influence the sample preparation technique were investigated. The method was then validated over a concentration range from 17.5 to 1950 ng/ml, the first concentration level corresponding to the lower limit of quantitation. At this concentration level, the mean bias and the R.S.D. value for intermediate precision were -2.4% and 4.2%, respectively.     

Simultaneous determination of ampicillin and metampicillin in biological fluids using high-performance liquid chromatography with column switching

A new high-performance liquid chromatographic method with column switching has been developed for the simultaneous determination of metampicillin and its metabolite ampicillin in biological fluids. The plasma, urine and bile samples were injected onto a precolumn packed with LiChrosorb RP-8 (25–40 μm) after simple dilution with an internal standard solution in 0.05 M phosphate buffer (pH 7.0). The polar plasma components were washed out using 0.05 M phosphate buffer (pH 7.0). After valve switching, the concentrated drugs were eluted in the back-flush mode and separated by an Ultracarb 5 ODS-30 column with a gradient system of acetonitrile-0.02 M phosphate buffer (pH 7.0) as the mobile phase. The method showed excellent precision, accuracy and speed with a detection limit of 0.1 μg/ml. The total analysis time per sample was less than 40 min and the coefficients of variation for intra- and inter-assay were less than 5.1%. This method has been successfully applied to plasma, urine and bile samples from rats after intravenous injection of metampicillin.     

Bifidobacteria Strain Behavior Toward Cholesterol: Coprecipitation with Bile Salts and Assimilation

Resting cells and growing cells of bifidobacteria strains exhibited an ability to remove cholesterol in the presence of bile salts. In resting cell assays, the removed cholesterol was precipitated in the presence of cholic acid at pH values lower than 5.4. However, this precipitated cholesterol was redissolved when the pellets were washed with phosphate buffer, pH 7, and no cholesterol was found in the cells. It appears that this precipitation is a transient phenomenon. In the case of growing cells, the removed cholesterol was partially recovered when cells were washed with phosphate buffer, pH 7, while the remaining cholesterol was extracted from the cells. Cultured in the presence of radiolabeled free or esterified cholesterol, bifidobacteria strains were able to assimilate esterified cholesterol. It is concluded that the removal of cholesterol from the growth medium by bifidobacteria strains is due to both bacterial assimilation and precipitation of cholesterol. Received: 8 February 1996/Accepted: 11 March 1996     

Histochemical Demonstration of Succinic Dehydrogenase in Ascites Tumor Cells

Fresh undiluted tumor ascites (0.05 ml) withdrawn from peritoneal cavity was placed immediately in a centrifuge tube containing 2.0 ml of an aqueous mixture prepared with 1 part each of the following solutions: 1% neotetrazolium chloride, 0.2 M sodium succinate and 0.1 M phosphate buffer, pH 7.4. The tube was incubated for 2 hr at 37°C and centrifuged for 3 min at 700 rev/min. The precipitate was washed with 0.85% saline solution and subsequently fixed with neutral 10% formalin for 10 min. After centrifugation, smears or squash preparations of the precipitate were prepared. Succinic dehydrogenase activity was demonstrated very distinctly and uniformly by the granular deposition of a deep purple pigment intracellularly.     

Staining Residual Lipids in Ultrathin Sections of Tissues Embedded in Polyester Resin

Rat suprarenal glands fixed in Palade's 1% OsO₄, buffered at pH 7.7 with veronal-acetate, to which 0.1% MgCl₂ was added, were embedded in Vestopal-W and sectioned at 0.2-1 µ. The sections were attached to slides by floating on water, without adhesive, and drying at 60-80° C, placed in acetone for 1 min and then treated with the following staining procedure: Place the preparation in a filtered solution of oil red O, 1 gm; 70% alcohol, 50 ml; and acetone, C.P., 50 ml; for 0.5-1 hr. Rinse in absolute ethyl alcohol; drain; counterstain with 0.5% aqueous thionin for 5 min; rinse in distilled water; drain; stain in 0.2% azure B in phosphate buffer at pH 9, for 5 min. Dry and apply a drop of immersion oil directly on the section. The preparations are temporary. Ciaccio-positive lipids, rendered insoluble by OsO, fixation, stained red to ochre.     

On the mechanism of hemozoin production in malaria parasites: activated erythrocyte membranes promote beta-hematin synthesis

The ferriprotoporphyrin IX (FP) molecules released by intraerythrocytic malaria parasites during hemoglobin digestion are converted to beta-hematin and are stored in the parasites' food vacuoles. It has been demonstrated in cell-free medium that the incorporation of FP into beta-hematin under physiological conditions requires a catalyst from parasite lysates or pre-formed beta-hematin. In the present studies, lysates of Plasmodium falciparum-infected erythrocytes were suspended in 1 M NaOH and were washed with phosphate buffer, pH 7.6. When the cell extracts were incubated with hematin in 0.5 M sodium acetate buffer, pH 5, for 20 hr at 37 degrees C, a large quantity of beta-hematin was formed. To determine whether parasite components were necessary for the beta-hematin formation, normal erythrocyte ghosts were similarly treated with 1 M NaOH and then incubated with hematin. In repeated experiments it was found that, on the average, 70% of the hematin was converted to beta-hematin. Membranes treated with HCl or CH(3)COOH also promoted the formation of beta-hematin, while untreated membranes were ineffective. The possibility that metabolic activities in the food vacuoles of malaria parasites may activate membrane fragments, from hemoglobin vesicles, to promote beta-hematin formation is discussed in this paper.     

A Buffered Giemsa-Bodian Stain for Neurological Material

A buffered Giemsa counterstain for the Bodian method is described. It is very useful for bringing out Nissl substance and nerve fibers in the same section. Bouin perfused or formalin fixed material from mammals, amphibia, reptiles and fish was used. After fixation, all tissues were decalcified for at least a week in 50% formic acid (1 part) and 20% sodium citrate (1 part). This was washed out thoroughly. The method described by Bodian (1936) was followed except for the following minor changes: Winthrop Protargol (Strong Protein Silver) Batch N346BJ was used exclusively; all glassware was cleaned with acid prior to setting up the stain; before developing, the sections were washed in warm tap water for 10 minutes; the gold chloride was chilled before use. The sections were then put into buffered Giemsa for 24 hours. Stock Giemsa: 0.75 grams powdered Giemsa (Coleman and Bell, Certification No. CGe-3) was dissolved in 50 ml. of glycerin overnight in the oven, then 50 ml. of methyl absolute alcohol were added. To 3 ml. of Giemsa stock solution, 87 ml. of distilled water buffered to pH 5.3 with 10 ml. of Sorensen's buffers were added and the solution filtered. Coleman buffer tablets gave best results at pH 5.0. Sections were then rinsed in 95% alcohol, two changes of absolute alcohol, two changes of xylene, and were then mounted in Clarite.     

Antigen retrieval trial for post-embedding immunoelectron microscopy by heating with several unmasking solutions.

A novel antigen retrieval procedure was carried out in the post-embedding immunogold electron microscopy method to improve the stainability of the samples. This was done by weakly fixing cultured Helicobacter pylori (ATCC43504) and embedding in Lowicryl K4M. Before staining with the anti-H. pylori antibody, the ultrathin sections were mounted on a nickel grid and heated at 121C for 15 min, 99C for 40 min, and 65C for 24 hr in distilled water, 0.1 M phosphate buffer (pH 7.4), 0.01 M EDTA (pH 7.2), 0.05 M Tris buffer (pH 10.0), 0.8 M urea (pH 7.2), 0.01 M citric acid (pH 6.0), or a commercially available target unmasking fluid (S1699; pH 6.0). Antigen retrieval in the Tris buffer solution generally showed better stainability than the classical post-embedding method without any antigen retrieval. At 65C for 24 hr, better stainability of the ultrasections was observed for each of the solutions used except for the phosphate buffer compared to the control. We suggest that the antigen retrieval method should be applied for routine use even by in post-embedding immunogold electron microscopy.     

Permanent Mounting of Unstained and Aceto-Orcein Stained Cells in the Water-Soluble Medium, Abopon

For cellular morphology, mammalian cells were grown on cover slips in Leigh ton tubes, fixed in 1% osmic acid vapor for 2 min, decolorized with 30% H₂O₂ in 5% ammonium oxalate solution (1:7) for 2 min, then washed thoroughly, and finally mounted in a water-soluble medium consisting of a saturated solution of Abopon in 0.2 M phosphate buffer, pH 7.0. For chromosomal analysis of similarly cultured cells, aceto-orcein preparations were made by conventional methods, with the following minor modifications: following pretreatment with colchicine and hypotonic expansion, the cells on the cover slips were fixed in acetic-alcohol (1:3), air dried, incubated at 37° C for 15 min in 2% orcein in 45% acetic acid, rinsed in 45% acetic acid, washed several times in distilled water, and finally mounted in Abopon mounting medium. Both kinds of preparations were allowed to harden for 24 hr before being handled. Such slides will keep for years at room temperature. Studies requiring frequent comparisons of cellular and chromosomal morphology of cultured cells can thus be extended over long periods of time.     

Purification and characterization of cell-associated glucosyltransferase synthesizing insoluble glucan from Streptococcus mutans serotype c

Streptococcus mutans Ingbritt (serotype c) was shown to have a significant amount of cell-associated glucosyltransferase activity which synthesizes water-insoluble glucan from sucrose. The enzyme was extracted from the washed cells with SDS, renatured with Triton X-100, adsorbed to 1,3-alpha-D-glucan gel, and then eluted with SDS. The enzyme preparation was electrophoretically homogeneous, and the specific activity was 7.3 i.u. (mg protein)-1. The enzyme had an Mr of 158,000 as determined by SDS-PAGE, and was a strongly hydrophilic protein, as judged by its amino acid composition. The enzyme gradually aggregated in the absence of SDS. The enzyme had an optimum pH of 6.5 and a Km value of 16.3 mm for sucrose. Activity was stimulated 1.7-fold by dextran T10, but was not stimulated by high concentrations of ammonium sulphate. Below a sodium phosphate buffer concentration of 50 mm, activity was reduced by 75%. This enzyme synthesized an insoluble D-glucan consisting of 76 mol% 1,3-alpha-linked glucose and 24 mol% 1,6-alpha-linked glucose.     

Increase of electrical properties using a novel mixed buffer system in an enzyme fuel cell

Environment-friendly biocatalytic energy is considered to represent an attractive alternative to chemical catalystbased cells due to its renewability and better operation at low temperature. However, electrical biocatalysts have a low activity and electrical power. For increasing electrical properties of biocatalyst, a novel mixed buffer (phosphate and 3-morpholinopropanesulfonic acid (MOPS)) system was applied to an enzyme-based biofuel cell with microperoxidase (MP-11)-modified Au electrode. The cathodic electrical properties were increased by the phosphate and MOPS-mixed buffer solution. It was identified that the novel mixed buffer system obtained stronger ionic strength from phosphate buffer and better enzyme activity from MOPS buffer. The highest results of cyclic voltammetry were obtained when the proportion of phosphate to MOPS was nearly 1:1 and the pH was 7.0∼7.3. In addition, the novel mixed buffer led to the maximum power density (ca. 62.7 μW/cm²) in a basic enzymatic fuel cell (EFC).     

Staining Procedures for Ultrathin Sections of Tissues Embedded in Polyester Resin

Tissues were fixed for 30 min In cold (0-2° C) 1% OsO₄ (Palade) buffered at pH 7.7, to which 0.1% MgCl₂ was added. Dehydration was in a graded ethanol series (containing 0.5% MgCl₂) at 0-2° C, and terminated with 2 changes of absolute ethanol. Tissues were then transferred by a graded series to anhydrous acetone. Infiltration of the tissue with Vestopal-W (a polyester resin), is gradual with the aid of graded solutions of Vestopal-W in acetone. The infiltrated tissue is encapsulated and initial polymerization is done under ultraviolet light at room temperature for 8-16 hr. This is followed by final hardening at 60° C for 36-48 hr. Sections (0.2-1 μ) were cut, dried on slides, placed in acetone for 1 min and then treated by either of the following staining procedures: (1) Thionin-azure-fuchsin staining: Flood the preparation with 0.2% aqueous thionin and heat to 60-80° C for 3 min; if the preparation begins to dry, add stain. Rinse in distilled water. Flood the slide with 0.2% azure B in phosphate buffer at pH 9. Heat to 60-80° C for 3 min; do not permit the preparation to dry. Rinse in distilled water. Dip the slide in MacCallum's variant of Goodpasture's carbol-fuchsin stain for 1-2 sec. Rinse in distilled water. Check the preparation microscopically for intensity of the fuchsin stain. Repeat dips as may be needed to obtain the desired intensity. Rinse in distilled water. Dehydrate quickly in 95% and absolute alcohol; clear in 2 changes of xylene and cover in Permount or similar synthetic resin. (2) Thionin-azure counterstain for the periodic acid-Schiff reaction: Oxidize the tissue in 0.5% periodic acid for 15 min and transfer to Schiff's leucofuchsin solution for 30 min. Counterstain with 0.5% aqueous thionin for 3 min; wash in distilled water; stain in 0.2% azure B in phosphate buffer at pH 5.5; wash in distilled water; dehydrate; clear and cover as in the first method. For temporary preparations let dry after absolute alcohol and apply a drop of immersion oil directly on the section.