Oxazine Dyes. Iv. Simultaneous Nuclear and Double-Contrast Cytoplasmic Staining from A Single Solution

A dye mixture, consisting of a celestine blue B dispersion (prepared according to Gray et al. 1956), orange G, and acid fuchsin in one solution, simultaneously stains nuclear elements and gives double contrast staining of cytoplasmic elements. Orange G, 0.16 gm, and acid fuchsin, 0.04 gm, dissolved in 100 ml of celestine blue B dispersion and adjusted to pH 0.8 gives, when applied for 1.5 min, results comparable or superior to other “triple contrast” stains on a wide variety of tissues. No differentiation other than that which occurs during dehydration is necessary.     

Oxazine Dyes. I. Celestine Blue B with Iron as a Nuclear Stain

It is suggested that celestine blue B can stain as a colloidal dispersion, the nuclear specificity of which is controlled by the pH. The staining solution is prepared by adding 0.5 ml of concentrated H₂SO₄ to 1 gm of celestine blue B and dissolving the resultant granular mass in 100 ml of 2.5% ferric alum containing 14 ml of glycerol. Sections of amphibian, avian, and mammalian tissue placed for 1 min in this solution and then rinsed in water show as sharp nuclear staining as that usually produced by hematoxylin. A wide variety of fixatives is permissible. Overstaining is not possible within reasonable limits of exposure and no differentiation nor bluing is required. Both the staining solution and stained slides are stable.     

Oxazine Dyes. 2. Celestine Blue B, Gallocyanin and Gallamin Blue with Mordants Other Than Ferric Alum

Experiments with 3 oxazine dyes with 19 mordants failed to produce a more satisfactory staining solution than that recorded by Gray et al. (1956). The most practical solution developed is prepared by adding 0.4 ml concentrated HNO₃ to 1gm celestine blue B and dissolving the resulting mass in 100 ml 5% cupric nitrate containing 14 ml glycerol. This solution is less acid (pH 1.4) than the celestine blue B-ferric alum solution (pH 0.8) previously recommended. It gives as intense and sharp a stain but is slightly less stable. Formulae are given for four other combinations of possible practical application.     

A Hematoxylin and Eosin-Like Stain for Glycol Methacrylate Embedded Tissue Sections

A staining procedure is described for use with glycol methacrylate embedded tissue sections which does not stain the plastic embedment or remove the sections from the glass slides. The basic dye is celestine blue B. It is prepared by treating 1 g of the dye with 0.5 ml concentrated sulfuric acid. It is then dissolved with the following solution. Add 14 ml glycerine to 100 ml 2.5 percent ferric ammonium sulfate and warm the solution to 50 C. Finally adjust the pH to 0.8 to 0.9 The acid staining solution consists of 0.075 percent ponceau de xylidine and 0.025 percent acid fuchsin in 10 percent acetic acid. Slides containing the dried plastic sections are immersed in the celestine blue solution for five minutes and in the ponceau-fuchsin solution for ten minutes with an intervening water rinse. After a final wash, the sections are air dried and coverslipped. This staining procedure colors the tissues nearly the same as hematoxylin and eosin procedures.     

A simple polychrome stain for conventionally fixed Epon-embedded tissues.

The described technique, based upon a one-step Mallory-Heidenhain stain, can be applied as a routine stain for glutaraldehyde or OsO4 fixed, Epon embedded tissues of various organs. The technique consists of a short treatment of the sections with H2O2, a nuclear staining with celestine blue B and a final staining in a modified Cason's solution. The different tissue and cell components are displayed as follows: dark brown nuclei, yellow cytoplasm, red collagen fibers and blue elastic fibers. Intracytoplasmic components as glycogen and mucus are stained respectively blue and violet, whereas other inclusions such as leucocyte granules are colored orange to red.     

An Evaluation of Some Aniline Dyes as Nuclear Stains in Trichrome Procedures

A comparison of the utility of gallocyanin, gallamine blue, celestine blue B and acid alizarin blue BB as nuclear stains for material to be counterstained by the van Gieson, Kornhauser, Gomori and Masson technics has been made. With all these nuclear stains except gallocyanin there were definite deficiencies. However, gallocyanin routinely has given excellent results and can be highly recommended. This dye is not specific for nucleic acids but rather stains some material with much the same spatial distribution in the cell as the nucleic acids.     

A Simple Polychrome Stain for Conventionally Fixed Epon-Embedded Tissues

The described technique, based upon a one-step Mallory-Heidenhain stain, can be applied as a routine stain for glutaraldehyde or OsO₄ fixed, Epon embedded tissues of various organs. The technique consists of a short treatment of the sections with H₂O₂, a nuclear staining with celestine blue B and a final staining in a modified Cason's solution. The different tissue and cell components are displayed as follows: dark brown nuclei, yellow cytoplasm, red collagen fibers and blue elastic' fibers. Intra cytoplasmic components as glycogen and mucus are stained respectively blue and violet, whereas other inclusions such as leucocyte granules are colored orange to red.     

Additional Schiff-Type Reagents for Use in Cytochemistry

Twenty-four new Schiff-type reagents were discovered in a survey of 140 different dyes. These dyes include acid fuchsin, acridine yellow, acriflavine hydrochloride, azure C., Bismarck brown R, Bismarck brown Y, celestine blue B, chrysoidine 3R, chrysoidine Y extra, cresyl violet, crystal violet, gentian violet, methylene blue, neutral violet, phenosafranin, phosphine GN, proflavine, toluidine blue O, and toluylene blue. Positive results obtained with crystal violet and a few samples of methylene blue are considered due to impurities. Various chemical extractions, aldehyde blocking reagents, and enzymatic treatments were used to verify the aldehyde specificity of the above dye-SO₂, reagents as well as azure A, brilliant cresyl blue, neutral red, safranin O, and thionin which have been mentioned by other workers. These reagents were tested in the Feulgen reaction for DNA and the PAS reaction for polysaccharides. Absorption curves were obtained from individual nuclei stained for DNA. The absorption peaks ranged from 450 mμ, to 630 mμ. depending on the dye studied. The Feulgen reaction could be followed by the PAS reaction or vice versa in mouse intestine using reactive dyes of complementary colors. The evidence indicates that a potential Schiff-type reagent must have at least one free NH₂ group on the dye molecule.     

News from the Biological Stain Commission

Abstract

The origins of repeated hematoxylin shortages are outlined. Lack of integration in the hematoxylin trade exacerbates the problems inherent in using a natural product. Separate corporations are engaged in tree growth and harvesting, dye extraction, processing of extracts to yield hematoxylin, and formulation and sale of hematoxylin staining solutions to the end users in biomedical laboratories. Hematoxylin has many uses in biological staining and no single dye can replace it for all applications. Probably, the most satisfactory substitutes for aluminum-hematoxylin (hemalum) are the ferric complexes of celestine blue (CI 51050; mordant blue 14) and eriochrome cyanine R (CI 43820; mordant blue 3, also known as chromoxane cyanine R and solochrome cyanine R). The iron-celestine blue complex is a cationic dye that binds to nucleic acids and other polyanions, such as those of cartilage matrix and mast cell granules. Complexes of iron with eriochrome cyanine R are anionic and give selective nuclear staining similar to that obtained with acidic hemalum solutions. Iron complexes of gallein (CI 45445; mordant violet 25), a hydroxyxanthene dye, can replace iron-hematoxylin in formulations for staining nuclei, myelin, and protozoa.     

Early biochemical and histological alterations in rat corticoencephalic cell cultures following metabolic damage and treatment with modulators of mitochondrial ATP-sensitive potassium channels

The present study was aimed at characterizing alterations of the nucleotide content and morphological state of rat corticoencephalic cell cultures subjected to metabolic damage and treatment with modulators of mitochondrial ATP-dependent potassium channels (mitoK(ATP)). In a first series of experiments, in vitro ischemic changes of the contents of purine and pyrimidine nucleoside diphosphates and triphosphates were measured by high performance liquid chromatography (HPLC) and the corresponding histological alterations were determined by celestine blue/acid fuchsin staining. As an ischemic stimulus, incubation with a glucose-free medium saturated with argon was used. Ischemia decreased the levels of adenosine, guanine and uridine triphosphate (ATP, GTP, UTP) and increased the levels of the respective dinucleotides ADP and UDP, whereas the GDP content was not changed. Both 5-hydroxydecanoate (5-HD) and diazoxide failed to alter the contents of nucleoside diphosphates and triphosphates, when applied under normoxic conditions. 5-HD (30 microM) prevented the ischemia-induced changes of nucleotide and nucleoside levels. Diazoxide (300 microM), either alone or in combination with 5-hydroxydecanoate (30 microM) was ineffective. Pyruvate (5 mM) partially reversed the effects of ischemia or ischemia plus 2-deoxyglucose (20mM) in the incubation medium. Diazoxide (300 microM) and 5-HD (30 microM) had no effect in the presence of pyruvate (5mM) and 2-deoxyglucose (20mM). Staining the cells with celestine blue/acid fuchsin in order to classify them as intact, reversibly or profoundly injured, revealed a protective effect of 5-HD. When compared with 5-HD, diazoxide, pyruvate and 2-deoxyglucose had similar but less pronounced effects. In conclusion, these results suggest a protective role of 5-hydroxydecanoate on early corticoencephalic nucleotide and cell viability alterations during ischemia.     

Block Staining of Botanical Materials

Plant materials, including coleus stem tips, Psilotum stems and onion root tips, were stained in iron-mordanted celestine blue and safranin (Gray and Pickle 1956) prior to embedding and sectioning. Mitotic figures as well as general morphological and anatomical features are adequately stained by this procedure. The plant materials, subdivided so that the largest dimension is about 8-10 mm, are stained for 12-48 hr. The time is dependent upon the tissue and dilution of the stain used. Excess stain is washed out and the tissues are dehydrated, embedded, sectioned and mounted on slides in the usual manner. Following removal of the wax by xylene the sections may be counterstained, or a cover slip may be added immediately.     

A Tetrachrome Stain for Fresh, Mineralized Bone Sections, Useful in the Diagnosis of Bone Diseases

Fresh, unprocessed bone is ground to sections 75-100 μ thick, stained in an aqueous solution composed of fast green FCF, 0.1 gm; orange G, 2.0 gm; distilled water, 100.0 ml; and adjusted to pH 6.65, then in a mixture of 1 part alcoholic solution of 0.25% celestine blue B and 9 parts of alcoholic solution of 0.1% basic fuchsin. Surface stain is removed by grinding sections to 50 μ and washing them in 1% invert soap (Zephiran) to remove adherent debris. (Commercial detergents and alkaline soaps may interfere with chromophore groups of the dyes.) Wash in tap water; rinse in distilled water and differentiate in 1% acetic alcohol. Dehydrate in ascending alcohols, clear in xylene and mount permanently in a neutral, synthetic resin. Active osteoid seams stain dark to light green; resting osteoid seams, red to bright orange red; transitional osteoid seams, geenish-yellow, orange red to red; older, partly mineralized matrix, orange; new, partly mineralized matrix, red; osteocyte nuclei, red; osteoblasts and osteoclasts, greenish-blue to dark purple nuclei and green or light green cytoplasm. Hyper-trophic and differentiating cartilage cells are stained light pink and dark red respectively. The staining reactions are consistent; the solutions are stable.     

3,4-Dihydroxyxanthone dioxygenase from Arthrobacter sp. strain GFB100.

Bacterial extradiol ring-fission dioxygenases play a critical role in the transformation of multiring aromatic compounds to more readily biodegradable aromatic or aliphatic intermediates. Arthrobacter sp. strain GFB100 utilizes an extradiol meta-fission dioxygenase, 3,4-dihydroxyxanthone dioxygenase (DHXD), in the catabolism of the three-ring oxygen heterocyclic compound xanthone. In this paper, we show that DHXD is a cytosolic enzyme, induced by growth on xanthone and maximally expressed during the stationary phase of growth. In addition, we characterize the DHXD activity in terms of its basic enzymological properties. 1,10-Phenanthroline and H2O2 treatments eliminated DHXD activity, indicating that the enzyme required Fe2+ ions for activity. Other divalent cations were either inhibitory or had no effect on activity. DHXD had a temperature optimum of 30 degrees C and a pH optimum of 7.0. DHXD followed typical saturation kinetics and had an apparent Km of 10 microM for 3,4-dihydroxyxanthone. The dye celestine blue served as a noncompetitive DHXD inhibitor (Ki, 5 microM). Several other structural analogs served neither as substrates nor inhibitors. DHXD was thermally labile at temperatures above 40 degrees C. The half-life for thermal DHXD inactivation was 5 min at 40 degrees C. DHXD activity was completely stable through one freeze-thaw cycle, and about 80% of the DHXD activity remained after 2 days of incubation at 0 degree C. The apparent tight binding of the Fe2+ cofactor to DHXD may be a factor contributing to the stability of this extradiol dioxygenase when it is stored.     

Microspectrophotometric Studies of Romanowsky Stained Blood Cells. III. The Action of Methylene Blue and Azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

3,4-Dihydroxyxanthone dioxygenase from Arthrobacter sp. strain GFB100.

Bacterial extradiol ring-fission dioxygenases play a critical role in the transformation of multiring aromatic compounds to more readily biodegradable aromatic or aliphatic intermediates. Arthrobacter sp. strain GFB100 utilizes an extradiol meta-fission dioxygenase, 3,4-dihydroxyxanthone dioxygenase (DHXD), in the catabolism of the three-ring oxygen heterocyclic compound xanthone. In this paper, we show that DHXD is a cytosolic enzyme, induced by growth on xanthone and maximally expressed during the stationary phase of growth. In addition, we characterize the DHXD activity in terms of its basic enzymological properties. 1,10-Phenanthroline and H2O2 treatments eliminated DHXD activity, indicating that the enzyme required Fe2+ ions for activity. Other divalent cations were either inhibitory or had no effect on activity. DHXD had a temperature optimum of 30 degrees C and a pH optimum of 7.0. DHXD followed typical saturation kinetics and had an apparent Km of 10 microM for 3,4-dihydroxyxanthone. The dye celestine blue served as a noncompetitive DHXD inhibitor (Ki, 5 microM). Several other structural analogs served neither as substrates nor inhibitors. DHXD was thermally labile at temperatures above 40 degrees C. The half-life for thermal DHXD inactivation was 5 min at 40 degrees C. DHXD activity was completely stable through one freeze-thaw cycle, and about 80% of the DHXD activity remained after 2 days of incubation at 0 degree C. The apparent tight binding of the Fe2+ cofactor to DHXD may be a factor contributing to the stability of this extradiol dioxygenase when it is stored.     

Microspectrophotometric studies of Romanowsky stained blood cells. III. The action of methylene blue and azure B

The performances of two standardized Romanowsky stains (azure B/eosin and azure B/methylene blue/eosin) have been compared with each other and with a methylene blue/eosin stain. Visible-light absorbance spectra of various hematological substrates have been measured. These have been analyzed in terms of the quantities of bound azure B, methylene blue and eosin dimers and monomers, and in terms of the CIE color coordinates. It has been found that the addition of methylene blue to azure B/eosin produces little change in performance, at least using these two analytical methods. Methylene blue/eosin does not produce the purplish colorations typical of the Romanowsky effect. This is due not to differences between the spectra of methylene blue and azure B, but to the fact that methylene blue does not facilitate the binding of eosin to cellular substrates to the same extent as azure B.     

Zinc Chloride Methylene Blue, Ii. Preparation of Giesma and Wright Type Low Azure B Blood Stains from Dichromate Oxidized Commercial Dye

TO determine the amount of K₂Cr₂O₇ required to produce optimal Giemsa type staining, six 1 g amounts (corrected for dye content) of zinc methylene blue were oxidized with graded quantities of K₂Cr₂O₇ to produce 4, 8, 12, 16, 20 and 24% conversion of methylene blue to azure B. These were heated with a blank control 15 minutes at 100 C in 60-65 ml 0.4 N HCI. cooled, and adjusted to 50 ml to give 20 mg original dye/ml. Aliquots were then diluted to 1% and stains were made by the “Wet Giemsa” technic (Lillie and Donaldson 1979) using 6 ml 1% polychrome methylene blue, 4 ml 1% cosin (corrected for dye content), 2 ml 0.1 M pH 6.3 phosphate buffer, 5 ml acetone, and 23 ml distilled water. The main is added last and methanol fixed blood films are stained immediately for 20-40 min.

For methylene blue supplied by MCB 12-H-29, optimal stains were obtained with preparations containing 20 and 24% conversion of methylene blue to azure B. With methylene blue supplied by Aldrich (080787), 16% conversion of methylene blue to azure B was optimal. Eosinates prepared from a low azure B/methylene blue preparation selected in this way give good stains when used as a Wright stain in 0.3% methanol solution. However, when the 600 mg eosinate solution in glycerol methanol is supplemented with 160 mg of the same azure B/methylene blue chloride the mixture fails to perform well. The HCI precipitation of the chloride apparently produces the zinc methylene blue chloride salt which is poorly soluble in alcohol. It appears necessary to have a zinc-free azure B/methylene blue chloride to supplement the probably zinc-free eosinate used in the Giemsa mixture.     

ON THE NATURE OF THE DYE PENETRATING THE VACUOLE OF VALONIA FROM SOLUTIONS OF METHYLENE BLUE

When uninjured cells of Valonia are placed in methylene blue dissolved in sea water it is found, after 1 to 3 hours, that at pH 5.5 practically no dye penetrates, while at pH 9.5 more enters the vacuole. As the cells become injured more dye enters at pH 5.5, as well as at pH 9.5. No dye in reduced form is found in the sap of uninjured cells exposed from 1 to 3 hours to methylene blue in sea water at both pH values. When uninjured cells are placed in azure B solution, the rate of penetration of dye into the vacuole is found to increase with the rise in the pH value of the external dye solution. The partition coefficient of the dye between chloroform and sea water is higher at pH 9.5 than at pH 5.5 with both methylene blue and azure B. The color of the dye in chloroform absorbed from methylene blue or from azure B in sea water at pH 5.5 is blue, while it is reddish purple when absorbed from methylene blue and azure B at pH 9.5. Dry salt of methylene blue and azure B dissolved in chloroform appears blue. It is shown that chiefly azure B in form of free base is absorbed by chloroform from methylene blue or azure B dissolved in sea water at pH 9.5, but possibly a mixture of methylene blue and azure B in form of salt is absorbed from methylene blue at pH 5.5, and azure B in form of salt is absorbed from azure B in sea water at pH 5.5. Spectrophotometric analysis of the dye shows the following facts. 1. The dye which is absorbed by the cell wall from methylene blue solution is found to be chiefly methylene blue. 2. The dye which has penetrated from methylene blue solution into the vacuole of uninjured cells is found to be azure B or trimethyl thionine, a small amount of which may be present in a solution of methylene blue especially at a high pH value. 3. The dye which has penetrated from methylene blue solution into the vacuole of injured cells is either methylene blue or a mixture of methylene blue and azure B. 4. The dye which is absorbed by chloroform from methylene blue dissolved in sea water is also found to be azure B, when the pH value of the sea water is at 9.5, but it consists of azure B and to a less extent of methylene blue when the pH value is at 5.5. 5. Methylene blue employed for these experiments, when dissolved in sea water, in sap of Valonia, or in artificial sap, gives absorption maxima characteristic of methylene blue. Azure B found in the sap collected from the vacuole cannot be due to the transformation of methylene blue into this dye after methylene blue has penetrated into the vacuole from the external solution because no such transformation detectable by this method is found to take place within 3 hours after dissolving methylene blue in the sap of Valonia. These experiments indicate that the penetration of dye into the vacuole from methylene blue solution represents a diffusion of azure B in the form of free base. This result agrees with the theory that a basic dye penetrates the vacuole of living cells chiefly in the form of free base and only very slightly in the form of salt. But as soon as the cells are injured the methylene blue (in form of salt) enters the vacuole. It is suggested that these experiments do not show that methylene blue does not enter the protoplasm, but they point out the danger of basing any theoretical conclusion as to permeability on oxidation-reduction potential of living cells from experiments made or the penetration of dye from methylene blue solution into the vacuole, without determining the nature of the dye inside and outside the cell.     

The purification of methylene blue and azure B by solvent extraction and crystallization.

Detailed schemes are described for the preparation of purified methylene blue and azure B from commercial samples of methylene blue. Purified methylene blue is obtained by extracting a solution of the commercial product in an aqueous buffer (pH 9.5) with carbon tetrachloride. Methylene blue remains in the aqueous layer but contaminating dyes pass into the carbon tetrachloride. Metal salt contaminants are removed when the dye is crystallized by the addition of hydrochloric acid at a final concentration of 0.25 N. Purified azure B is obtained by extracting a solution of commercial methylene blue in dilute aqueous sodium hydroxide (pH 11-11.5) with carbon tetrachloride. In this pH range, methylene blue is unstable and yields azure B. The latter passes into the carbon tetrachloride layer as it is formed. Metal salt contaminants remain in the aqueous layer. A concentrated solution oa azure B is obtained by extracting the carbon tetrachloride layer with 4.5 X 10(-4)N hydrobromic acid. The dye is then crystallized by increasing the hydrobromic acid concentration to 0.23 N. Thin-layer chromatography of the purified dyes shows that contamination with related thiazine dyes is absent or negligible. Ash analyses reveal that metal salt contamination is also negligible (sulphated ash less than 0.2%).     

The azure dyes: their purification and physicochemical properties. II. Purification of azure B.

A method is described for the purification of the dye azure B in quantities sufficient for biological staining experiments on a larger scale. The method is based on the use of column chromatography. Two columns are employed. In column A with silica gel as adsorbent the azure B fraction is isolated from a suitable substrate ('technical' azure B gained by a modification of Bernthsen's synthesis of methylene blue, or polychrome methylene blue) using an acetate-formate mixture as eluent. In column B, on an Amberlite polymeric adsorbent (XAD-2) the acetate-formate anions are exchanged in chloride. Regeneration of both columns is possible: KMnO4, Na2S2O4 and water are run through column A; 5% NaOH, methanol and water through column B. Purification of azure B on economic terms is thus attained. The opinion is expressed that this method is also applicable to the purification of other cationic dyes.