Selective Demonstration of Histidine

Mounted paraffin sections of formalin-fixed tissue are treated for 24 hr at room temperature in an iodine solution (0.3% iodine, 0.6% potassium iodide) at pH 10 to block the aromatic nuclei of tyrosine and tryptophane. A coupled tetrazonium reaction using naphthanil diazo blue B (tetrazotized o-dianisidine) as a 0.1% solution at pH 9.2 for 15 min at 4°C, as the first coupling agent, and H acid (8-amino-1-naphthol-3, 6-dissulfonic acid), as a 2% solution at pH 9.2 for 15 min at 4°C, as the second coupling agent, stains sites of histidine a red-brown to red-purple color.     

Staining Mitochondria With Hematoxylin After Formalin-Sublimate Fixation; A Rapid Method

Mitochondria were stained in liver, kidney, pancreas, adrenal and intestinal mucosa of rat and mouse. Tissues 1 mm thick, were fixed in a mixture of saturated aqueous HgCl₂, 90 ml; formalin (37-38% HCHO), 10 ml, at room temperature (25°C) for 1 hr. Deparaffinized sections 3-4μ thick were treated with Lugol's iodine (U.S.P.) followed by Na₂S₂O₃ (5%), rinsed in water and the ribonucleic acid removed by any of the following procedures: 0.2 M McIlavaine's buffer, pH 7.0, 2 hr, or 0.2 M phosphate buffer, pH 7.0, 2 hr at 37°C; 0.1% aqueous ribonuclease, 2 hr at 37°C; 5% aqueous trichloracetic acid overnight at 37°C; or 1% KOH at room temperature for 1 hr. After washing in water, sections were treated with a saturated solution of ferric ammonium alum at 37°C for 8-12 hr and colored by Regaud's ripened hematoxylin for 18 hr. They were then differentiated in 1% ferric ammonium alum solution while under microscopic observation.     

Biosynthesis and properties of an extracellular metalloprotease from the Antarctic marine bacterium Sphingomonas paucimobilis

An extracellular protease from the marine bacterium Sphingomonas paucimobilis, strain 116, isolated from the stomach of Antarctic krill, Euphausia superba Dana, was purified and characterized. The excretion of protease was maximal at temperatures from 5 to 10°C, i.e. below the temperature optimum for the strain growth (15°C). The highly purified enzyme was a metalloprotease [sensivity to ethylenediaminetetraacetic acid (EDTA)] and showed maximal activity against proteins at 20–30°C and pH 6.5–7.0, and towards N-benzoyl-tyrosine ethyl ester (BzTyrOEt) at pH 8.0. At 0°C the enzyme retained as much as 47% of maximal activity in hydrolysis of urea denatured haemoglobin (Hb) (at pH 7.0), and at −5 and −10°C, 37 and 30%, respectively. The metalloprotease was stable up to 30°C for 15 min and up to 20°C for 60 min. These results indicate that the proteinase from S. paucimobilis 116 is a cold-adapted enzyme.     

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.     

A Rhodocyan Technic for Staining the Anterior Pituitary

A reproducible, one-step, differential staining technic which uses routine formalin-fixed tissue and gives brilliantly contrasting results is produced by incubating sections for 1 hr in a 60° C oven in the following dye mixture: 1% eosin B (CI#771), 8 ml; 1% anilin blue (CI#707), 2 ml; and buffer solution (0.1M citric acid, 1.1 ml; 0.2M Na₂HPO₄, 0.9 ml; distilled water, 28.0 ml) at pH 4.5. No differentiation is necessary. The method can be modified for duodenal enterochromaffin cells and alpha cells of pancreatic islets by adjusting the buffer to pH 3.6 and staining for only 3 min at 60° C.     

Immobilization of catalases from Bacillus SF on alumina for the treatment of textile bleaching effluents

A catalase preparation from a newly isolated Bacillus sp. was covalently immobilized on silanized alumina using glutaraldehyde as crosslinking agent. The effect of the coupling time of the enzyme-support reaction was determined in terms of protein recovery and immobilization yield and a certain balance point was found after which the activity recovery decreased. The activity profile of the immobilized catalase at high pH and temperature was investigated. The immobilized enzyme showed higher stabilities (214 h at pH 11, 30°C) at alkaline pH than the free enzyme (10 h at pH 11, 30°C). The immobilized catalase was inhibited by anionic stabilizers or surfactants added to the hydrogen peroxide substrate solution.     

A Celloidin Infiltration-Frozen Section Sequence for Enhanced Preservation of Phosphatases in Bone

The effect of the following embedding procedures on the acid and alkaline phosphatase content of decalcified mouse tibiae has been studied: embedding in 23% gelatine for 18 hr at 37° C, embedding in paraffin wax in vacuo for 1 hr at 58° C, and impregnation with 4% celloidin in diethyl ether and ethanol at 4° C for 2-3 days. Unsupported tissues were also used to demonstrate these enzymes for comparison with the above procedures. Tibiae were first fixed in 10% neutral formalin at 4° C for 15 hr, decalcified in equal volumes of 2% formic acid and 20% sodium citrate at pH 4.9 for not more than 5 days and then washed in distilled water before carrying out the embedding schedules. The celloidin-impregnated tibiae were placed in 70% ethanol to harden the celloidin and then washed in distilled water for 1-2 hr. These tibiae and those embedded in gelatine were cast in a gelatine block which was then hardened in 10% neutral formalin at 4° C for 2 hr. Sections of these and unsupported tibiae were cut at 15 μ on a freezing microtome. Decalcified tibiae embedded and blocked in paraffin wax were sectioned at 15 μ on a base sledge microtome. The enzymes were demonstrated using the coupling azo dye method given by Pearse (Histochemistry, 1st Ed. 1954). The stable diazotates of 4 benzoyl amino 2-5 diethoxyanilene, 3 nitro toluidine and o-dianisidine were used. Of the embedding procedures paraffin wax embedding produced the greatest loss of both enzymes. Gelatine embedding and infiltration with celloidin were equally good for the demonstration of acid phosphatase but for alkaline phosphatase the celloidin method was superior. The gelatine embedded material did not produce consistently good results. Celloidin-impregnated tibiae could be stored without marked deterioration of the enzyme content for longer than gelatine-embedded tibiae.     

Differentiated Staining of Osmium Tetroxide-Fixed, Vestopal-w-Embedded Tissue in thin Sections

Tissues were fixed at 20° C for 1 hr in 1% OsO₄, buffered at pH 7.4 with veronal-acetate (Palade's fixative), soaked 5 min in the same buffer without OsO₄, then dehydrated in buffer-acetone mixtures of 30, 50, 75 and 90% acetone content, and finally in anhydrous acetone. Infiltration was accomplished through Vestopal-W-acetone mixtures of 1:3, 1:1, 3:1 to undiluted Vestopal. After polymerisation at 60° C for 24 hr, 1-2 μ sections were cut, dried on slides without adhesive, and stained by any of the following methods. (1) Mayer's acid hemalum: Flood the slides with the staining solution and allow to stand at 20°C for 2-3 hr while the water of the solution evaporates; wash in distilled water, 2 min; differentiate in 1% HCl; rinse 1-2 sec in 10% NH,OH. (2) Iron-trioxyhematein (of Hansen): Apply the staining solution as in method 1; wash 3-5 min in 5% acetic acid; restain for 1-12 hr by flooding with a mixture consisting of staining solution, 2 parts, and 1 part of a 1:1 mixture of 2% acetic acid and 2% H₂SO₄ (observe under microscope for staining intensity); wash 2 min in distilled water and 1 hr in tap water. (3) Iron-hematoxylin (Heidenhain): Mordant 6 hr in 2.5% iron-alum solution; wash 1 min in distilled water; stain in 1% or 0.5% ripened hematoxylin for 3-12 br; differentiate 8 min in 2.5%, and 15 min in 1% iron-alum solution; wash 1 hr in tap water. (4) Aceto-carmine (Schneider): Stain 12-24 hr; wash 0.5-1.0 min in distilled water. (5) Picrofuchsin: Stain 24-48 hr in 1% acid fuchsin dissolved in saturated aqueous picric acid; differentiate for only 1-2 sec in 96% ethanol. (6) Modified Giemsa: Mix 640 ml of a solution of 9.08 gm KH₂PO₄ in 1000 ml of distilled water and 360 ml of a solution of 11.88 gm Na₂HPO₄-2H₂O in 1000 ml of distilled water. Soak sections in this buffer, 12 hr. Dissolve 1.0 gm of azur I in 125 ml of boiling distilled water; add 0.5 gm of methylene blue; filter and add hot distilled water until a volume of 250 ml is reached (solution “AM”). Dissolve 1.5 gm of eosin, yellowish, in 250 ml of hot distilled water; filter (solution “E”). Mix 1.5 ml of “AM” in 100 ml of buffer with 3 ml of “E” in 100 ml of buffer. Stain 12-24 hr. Differentiate 3 sec in 25 ml methyl benzoate in 75 ml dioxane; 3 sec in 35 ml methyl benzoate in 65 ml acetone; 3 sec in 30 ml acetone in 70 ml methyl benzoate; and 3 sec in 5 ml acetone in 95 ml methyl benzoate. Dehydrated sections may be covered in a neutral synthetic resin (Caedax was used).     

A new method for surface staining large slices of fixed brain using a copper phthalocyanine dye

Here we describe a method for gross staining of gray matter in slices of formaldehyde-fixed human brain. After protection of white matter with 4% phenol at 60°C for 5 min followed by a cold water wash, the gray matter was stained for 10-15 min at 20-25°C with 1% aqueous copper(II) phthalocyanine tetrasulfonic acid tetrasodium salt (CPTS). The staining resisted all attempts to be washed from the gray matter. Stained slices can be stored indefinitely in slightly acidified water, or plastinated as permanent dry specimens.     

Staining Tissue of the Central Nervous System with Luxol Fast Blue and Neutral Red

The tissue is fixed in 10% neutral saline formalin for 1 day to 3 wk depending on the size of the block, dehydrated and embedded in paraffin. The sections are stained at 57° C for 2 hr, then at 22° C for 30 min, in a 0.0125% solution of Luxol fast blue in 95% alcohol acidified by 0.1% acetic acid. They are differentiated in a solution consisting of: Li₂CO₃, 5.0 gm; LiOH-H₂O, 0.01 gm; and distilled water, 1 liter at 0-1° C, followed by 70% alcohol, and then treated with 0.2% NaHSO₃. They are soaked 1 min in an acetic acid-sodium acetate buffer 0.1 N, pH 5.6, then stained with 0.03% buffered aqueous neutral red. Sections are washed in distilled water, 1 sec, then treated with the following solution: CuSO₄·5H₂O, 0.5 gm; CrK(SO₄)₂·12H₂O, 0.5 gm; 10% acetic acid, 3 ml; and distilled water, 250 ml. Dehydration, clearing and covering complete the process. Myelin sheaths are stained bright blue; meninges and the adventitia of blood vessels are blue; red blood cells are green. Nissl material is stained brilliant red; axon hillocks, axis cylinders, ependyma, nuclei and some cytoplasm of neuroglia, media and endothelium of blood vessels are pink.     

Fuchsin staining with naoh clearing for lignified elements of whole plants or plants organs

Three methods that are adapted to the various consistencies of plants are as follows: 1. Samples are placed for 10-14 hr at 60° C in a 1% aqueous solution of basic fuchsin, to which 10 gm of solid NaOH per 100 ml are added. 2. Samples when taken out of 95% alcohol are placed in a 1% solution of basic fuchsin in 95% alcohol for 24 hr; after washing in water, they are placed in a 15% solution of NaOH at 60° C until cleared. 3. Samples are placed in a 15% aqueous solution of NaOH at 60° C until cleared, then for 24 hr at 60° C in 15% NaOH containing basic fuchsin. After being stained and cleared by one of these three methods, the samples are rinsed in water, dehydrated and then passed into a mixture of absolute alcohol and concentrated HC1 (3:1) for 1-15 min, rinsed in absolute alcohol, cleared in xylene and mounted in Canada balsam. The lignified tissues appear red; the others, transparent.     

Characteristics of galactomannanase for degrading konjac gel

Galactomannanase (Glmnase) is an enzyme product derived from Aspergillus niger. The activity of Glmnase degrading (hydrolyzing) the konjac gel were investigated. Significant loss in the enzyme activity was found when the temperature above 60 °C. Similar observations were obtained when the reaction pH above 5. Further increase in the pH value resulted in entirely loss of enzyme activity at the alkaline pH region (pH 8.0 and above). The optimal hydrolyzing temperature and pH were at 60 °C and 5.0, respectively. For the stability test, the purified Glmnase increased its thermostability up to 70 °C at pH 5.0, but it retained only about 60% activity after 60 min incubation at this temperature and its activity became zero after 20 min incubation at 80 °C. The Glmnase was stable at the pH range from 3.0 to 7.0 at room temperature and retained at least 80% activity for 60 min. For the storage temperature test, the lyophilized Glmnase still conserved about 90% activity during 7 days at 30 °C, and was higher than about 80% at 4 °C. The K_m and V_max, were 0.018 mg/ml konjac powder and 0.20 mg/ml reducing sugar per min, respectively.     

Permanent Smears of Leaf Tips for the Study of Chromosomes

Young leaf tips are soaked in a saturated aqueous esculin (aesculine) solution at 10-12° C for 15 min to 24 hr and fixed in acetic-alcohol, 1:1. The materials are then stained in a mixture of 2% aceto-orcein and 12V HCl (9:1), 3-4 sec over a flame followed by 30 min or longer at 30° C and then smeared in 1% aceto-orcein. Preparations are made permanent by loosening the cover glass in tertiary butyl alcohol and mounting directly in Canada balsam.     

Enhanced Differentiation of Zaprionus Chromosomes by Prestaining Acid Hydrolysis

Two variations of orcein staining have been adapted to salivary gland chromosomes of Zaprionus. Method I: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, stained with 2.5% orcein in 60% acetic add for 15-20 min, and squashed in 60% acetic acid. Method II: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, transferred to a saturated solution of carmine in 45% acetic acid for 1 min, then to a mixture of 50 ml of 1% orcein in concentrated lactic acid and 50 ml of 30% acetic add for 5 min. They are squashed in the same mixture. The unproved differentiation of chromosomes from cytoplasm is attributed to the removal of cytoplasmic ribonucleic add by add hydrolysis.     

Alkaline Phosphatase in Leucocytes by An Azo Dye Method

Alkaline phosphatase activity was demonstrated in the cytoplasm of leucocytes of man, rat and rabbit by means of naphthol AS phosphate as the substrate and fast blue BBN as the coupling agent. The reaction was effected in Tris buffer, 0.2 M at ph 9.1, in 5-10 min at 25°C. Air-dried smears, with or without fixation in 10% neutral formalin, showed activity but those heated 1 min in water at 100°C did not.     

Biocatalytic properties of a novel crude glycyrrhizin hydrolase from the liver of the domestic duck

A novel crude glycyrrhizin (GL) hydrolase preparation from the liver of domestic duck was used to produce glycyrrhetic acid monoglucuronide. To characterize the biocatalytic profiles of the crude enzyme, some effect factors were investigated. It had an apparent optimal pH of 6.0 and an optimal temperature at 55 °C. Most of the metal ions tested and ethylene diamine tetra acetic acid showed little effect on the crude enzyme activity except Cu²⁺. The enzyme was stable only at pH 6. It was more prone to inactivity at high pH conditions than at low pH conditions. It was stable at temperatures below 55 °C and it will lost 90% GL hydrolytic activity exposed at 70 °C. GL hydrolytic activity declined by 30% compared with the control in aqueous solution (buffer pH 6.0) when pre-equilibrated at 55 °C for 5 days. It indicated that the novel crude GL hydrolase preparation had good biocatalytic ability for selective hydrolysis of one glucuronic acid from GL.     

Gelatinization mechanism of potato starch

The non-Newtonian behavior and dynamic viscoelasticity of potato starch (Jaga kids red ’90, 21.0% amylose content) solutions after storage at 25 and 4°C for 24 h were measured with a rheogoniometer. The flow curves, at 25°C, of potato starch showed plastic behavior >1.0% (w/v) after heating at 100°C for 30 min. A gelatinization of potato starch occurred above 1.0% at room temperature. A very large dynamic viscoelasticity was observed when potato starch solution (3.0%) was stored at 4°C for 24 h and stayed at a constant value with increasing temperature. A small dynamic modulus of potato starch was observed upon addition of urea (4.0 M) at low temperature (0°C) even after storage at 25 and 4°C for 24 h. A small dynamic modulus was also observed in 0.05 M NaOH solution. Possible models of gelatinization and retrogradation mechanism of potato starch were proposed.     

Proton permeation, adenine nucleotide translocation and respiratory control in mitochondria cross-linked by dimethylsuberimidate

Rat liver mitochondria or isolated mitoplasts were treated with the cross-linking agent, dimethylsuberimidate, under conditions (pH 7.5; 0°C) which were not detrimental for the coupling quality of the mitochondria and the effect was evaluated on a kinetic basis. When about 25% of the NH₂-groups reacted, the mitochondria or the mitoplasts acquired complete osmotic stability. Succinate oxidation in state 4 was inhibited by about 30–35%. This effect was also observed when the organelles were amidinated by methylacetimidate, a monofunctional imidate which caused no osmotic stabilization. Uncouplers stimulated succinate oxidation in cross-linked mitochondria to the same extent as in the control, in contrast stimulation by ADP was suppressed. Accordingly, the rate of decay of the respiration-dependent cross-membrane proton gradient was only decreased by 25%, whereas the ATPase and adenine nucleotide translocase were strongly inhibited. In the cross-linked mitochondria, the extent of inhibition of the ATPase and of the translocase was found to be the same whether the assays were performed at 30°C (like the respiratory assay) or at 0°C. The effect of methylacetimidate treatment on these activities at the two temperatures was different. At 30°C, the ATPase was not inhibited and the extent of inhibition of ATP translocation was small. At 0°C, the two activities were nearly as much inhibited as in cross-linked mitochondria. Our results suggest that a considerable rigidity can be introduced in the coupling membrane by cross-linking, without a major loss in the initial step of energy conservation. However, the energy conserved in the proton gradient cannot be utilized for ATP synthesis, probably because of the restricted mobility of adenine nucleotide translocase in the cross-linked mitochondria.     

Some properties of levansucrase of Bacillus natto stabilized with periodate oxidized yeast glucomannan

It was observed that levansucrase from Bacillus natto became unstable and was easily inactivated when the salts were removed from the enzyme solution, while the enzyme was stable for long time in a buffered saline. After modification with periodate oxidized yeast glucomannan, the enzyme increased thermal stability up to 45°C, in which it conserved more than 90% of its activity after 15 min treatement. The optimum temperature was also shifted from 40°C in the case of original enzyme to 50°C for the modified enzyme after 10 min reaction time. The half-life time increased significantly from 9 min to 55 min at 50°C, however it increased from 30 min and 22 min respectively at 40°C and 45°C to more than 1 h at the same temperature. The content of carbohydrates of modified enzyme was 25% that increases the molecular weight from 57 KDa to 80 KDa. The products from sucrose by the modified enzyme were the same as the case using original enzyme. Namely, the products confirmed were levan and 3 kestoses (6-, 1-, and neo-kestose).     

Staining of fresh, Undecalcified, thin Bone Sections

Fresh, undecalcified bone sections can be reproducibly and reliably stained by any of the following procedures: (A) Basic fuchsin, 1% in 30% alcohol, 48 hr, 22°C. (B) AgNO₃, 0.033 M, 48 hr, 22°C; washing 48 hr in a large volume of distilled water; exposure to light to develop the color. (C) Metallic sulfides (Co⁺⁺, Pb⁺⁺, Hg⁺⁺, Cu⁺⁺): the nitrate of the metal, 0.033 M, 48 hr, 22°C; then Na₂S, 0.033 M, 48 hr, 22° C. (D) Alizarin Red S, 0.1% solution in distilled water, 48 hr, 22°C; differentiated 48 hr at 22°C in weakly alkaline water, pH about 8. (E) KMnO₄: boiling 8-10 min in a 0.1 N, solution. With the exception of D the surface stain must be ground off the section for microscopic examination of its interior. Stain concentration, time and temperature can be altered to suit specific needs.