Basic Fuchsin as A Nuclear Stain

Five distinct nuclear stains and staining procedures which utilize basic fuchsin as the dye have been studied, compared and tested on a Feulgen-weak fungus, Blastomyces dermatitidis, and other fungi.

Aqueous basic fuchsin has been shown to be an excellent, though impermanent, stain with which to study the nuclei of this and other fungi. The conditions under which formaldehyde acts as a mordant for basic fuchsin and produces a permanent nuclear stain have been established.

Comparison of crystal violet and basic fuchsin suggests that the mordanting action of the aldehyde operates through the para-amino groups of the dye. Certain other basic dyes were not mordanted by formaldehyde.

Gentle acid hydrolysis of the tissues has been found to be essential both to the specificity of the dye as a nuclear stain and to the mordanting effect of the aldehyde.

The possible relationship of these observations to the Feulgen reaction is discussed. A protocol for the method developed is presented.     

The Specificity of the Feulgen Reaction for Thymonucleic Acid

The results of experiments on the specificity of the Feulgen reaction for thymonucleic acid do not substantiate the observations of Carr. The staining is not localized in the nucleus because of the destruction of cytoplasmic constituents following acid hydrolysis or because of the absorbing power of chromatin, since the cytoplasm and nucleolus can still be stained by numerous dyes. The effects of factors such as the acid hydrolysis and sulfurous acid washing baths upon the cytologic distribution of dye were studied on tissues stained with (1) fuchsin-sulfurous-acid (Feulgen) reagent, (2) fuchsin-sulfurous-acid reagent colorized by the addition of formaldehyde, (3) basic fuchsin in one-tenth normal HCl, and (4) basic fuchsin in distilled water. Under comparable conditions, important differences between these stains were found in the effects of preliminary hydrolysis; rapidity of staining and destaining; extractability of dye from tissues by water, alcohol, and sulfurous acid solution; rate of fading from exposure to light; localization of stain in tissues; and differences in hue. After treating tissues with desoxyribonuclease, an enzyme which acts only upon thymonucleic acid, cells do not stain with the Feulgen technic. Following removal of nucleic acid from chromatin by hydrolysis, attempts to demonstrate an absorption of thymonucleic acid upon the residual nuclear protein were unsuccessful.

The evidence for and against the specificity is discussed. In agreement with most other investigators, on the basis of the evidence in the literature as well as these experiments, it is concluded that when properly controlled the Feulgen reaction is relatively specific for thymonucleic acid.     

Studies on the Preparation and Recoloration of Fuchsin Sulfurous Acid

Some of the factors affecting the recoloration of Schiff's Reagent (fuchsin sulfurous acid or FSA) by formaldehyde have been studied spectrophotometrically to determine the optimal conditions for the reaction of this reagent with aldehydes.

Of the various reducing agents utilized in the preparation of the leuco dye from basic fuchsin, sodium sulfite and bisulfite proved to be the most satisfactory for obtaining in the reagent maximal sensitivity to recoloration with minimal quantitative variation of results.

The relative proportions of reducing agent and basic fuchsin present in die leuco dye determine its sensitivity to recoloration. Under the conditions of the present experiments, greatest reagent recoloration was obtained when the leuco dye contained 0.01 mole of sodium bisulfite and 0.001 mole of basic fuchsin per 100 ml., a ratio of 10/1.

The recoloration of a given amount of FSA is related to the amount of aldehyde and the temperature of the reaction.

The present experiments indicate the desirability of standardizing the composition of FSA and the conditions under which it is used, if the results of different investigators are to be readily reproduced or compared.     

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.     

Further Experiments with the Masson Trichrome Modification of Mallory's Connective Tissue Stain

Several dyes, notably ponceau 2R, azofuchsin 3B, nitrazine yellow, and Biebrich scarlet may replace imported “ponceau de xylidin” in the Masson ponceau acid fuchsin mixture. Of these Biebrich scarlet appears to be the best and may be used without acid fuchsin.

A mixture of equal parts of 5% solutions of phosphomolybdic and phosphotungstic acids is much superior to either acid alone and gives adequate mordanting in 1 minute at 22°C.

With the fast green modification, times in plasma and fiber stains can be reduced to 2 minutes each. With anilin blue a 4-minute plasma stain is required. One-minute final differentiation in 1% acetic acid is adequate.

Primary mordanting of formalin material may be accomplished by 5 minutes in saturated aqueous mercuric chloride or 2 minutes in saturated alcoholic picric acid. Three minutes washing in running water is required after these mordants.     

Simplified Manufacture and Histochemical Use of the Schiff Reagent

Schiff reagents were made by two methods. The first procedure gave a Schiff reagent of pH 1.8-2.4. It was accomplished by passing sulfur dioxide into 0.5% aqueous fuchsin solution at room temperature, stopping at reddish violet, and decolorizing allowed to occur on standing. In another method, 1.5 ml. of 5.6% sulfurous acid was added to 100 ml. 0.5% fuchsin solution and the mixture produced in several hours a colorless Schiff reagent of pH 3. The solution remained unchanged for some weeks when kept stoppered in a refrigerator.

To test these Schiff reagents, histochemical examinations were carried out with Feulgen and McManus reaction in various pH ranges. These experiments showed that the Feulgen reaction was optimum at pH 3, the McManus reaction at pH 2.4.     

An Easily Controlled Regressive Trichromic Staining Method

Three modifications of Mallory's connective tissue stain are described and some features of the action of picric acid are discussed.

In the first and most critical method the nuclei are stained in an iron hematoxylin and then differentiated in a picric acid solution containing orange G. This not only differentiates the nuclei, but stains all other elements yellow. The section is then washed in running water to remove the yellow color from all tissues except those which are to remain yellow in the final preparation (usually the erythrocytes). The section is next stained in an acid fuchsin mixture and then differentiated until the desired depth and contrast is obtained. Staining in anilin blue follows and this in turn is differentiated to suit. The section is then dehydrated and mounted.

In the second method the nuclei are stained in hemalum (e.g. Harris's) for a short time; the section is then rinsed and immersed in a mixture of picric acid and acid fuchsin and thereafter is differentiated; it is next passed into anilin blue w. s. and then differentiated and mounted as before. This is less critical than method I, but can be applied to large batches of slides at a time.

The third method is a one-solution method. After staining the nuclei in hemalum, the section is immersed in the “Picro-Mallory” solution, differentiated briefly, dehydrated and mounted. This modification, while being the least critical, is most suitable for routine use when the tissues have been fixed in a fluid containing chromate; the other commonly used fixatives, while giving useful results, are not so good.     

Metallic Lakes of the oxazines (Gallamin Blue, Gallocyanin and Coelestin Blue) as Nuclear Stain Substitutes for Hematoxylin

Becher's investigations upon the soluble metallic lakes of the oxazines have been re-investigated, extended and results described. Gallamin blue, gallocyanin and coelestin blue in combination with ferric ammonium sulfate gave the best results. The dyes are dissolved in a five per cent aqueous solution of ferric ammonium sulfate. The solution is boiled for 2-3 minutes, cooled, filtered and ready for immediate use. The iron lakes of these dyes stain nuclei excellently giving a deep blue or blue black in 3-5 minutes. No differentiation with acid is required. Coelestin blue gives the most stable solution and is recommended as a routine nuclear stain. The protoplasm remains practically colorless and counter-staining with acid dyes such as ethyl-eosin, orange G, or fuchsin gives pictures which cannot be distinguished from a good hematoxylin stain.

Counter-staining with van Gieson solution is also possible. Benda's modification of the van Gieson solution is recommended. Staining of fat with Sudan, scarlet red, etc., does not interfere with nuclear staining by these dyes.

As applied to the central nervous system these dyes are far superior to hematoxylin. Ganglion and glia cells are as excellently stained as with thionin.

The most widely used fixatives, namely formaldehyde, Mueller-formaldehyde, Zenker's and alcohol, give equally as good results. The nature of the staining process is briefly discussed and a prospectus offered.     

Comparison of historic Grübler dyes with modern counterparts.

Seventeen Grübler dyes produced in Germany between 1880 and 1939 were examined in this study. These dyes were: fuchsin-bacillus, diamond fuchsin, fuchsin S acid, rubin S, safranin O water soluble, safranin yellowish water soluble, methyl eosin, Sudan III, scarlet R, auramine, orange G, aniline blue, pyronin, carmine, lithium carmine, hematein and aurantia. Spectrophotometry and staining characteristics were used to determine the maximum absorbance and efficacy of each dye in common staining techniques. The spectral curves and staining characteristics of these dyes compared well with modern dyes used as controls. Fuchsin bacillus and diamond fuchsin are synonyms for basic fuchsin. Fuchsin S acid and rubin S are synonyms for acid fuchsin. The scarlet R sample was the same as the Sudan III. The two safranins were the same. The basic fuchsin samples were unsuitable for preparation of Schiff's reagent. Both basic fuchsin and pyronin samples were less concentrated than modern counterparts. It is noteworthy that the dyes worked well after up to 100 years in storage, and this observation indicates that dyes can have a long shelf life when stored in cool, dry, air-tight conditions.     

Brilliant Cresyl Blue as a Stain for Plant Chromosomes

Methods are proposed for staining plant chromosomes with the dye brilliant cresyl blue, and for making these stained preparations permanent by using polyvinyl alcohol mounting medium.

The stain, which is composed of 2% brilliant cresyl blue in 45% aqueous acetic or propionic acid, is used with fixed material in making smear preparations. The technics for staining are similar to those employed in the aceto-carmine method.

The mounting medium is made by mixing 56% polyvinyl alcohol, which is diluted in water to the consistency of thick molasses, with 22% lactic acid and 22% phenol by volume. The permanent slides are made by floating off the cover slip of the temporary slide in 70% alcohol, then applying the mounting medium and replacing the cover slip.

The chief advantages of the methods described are:

1)The preparation of the stain is rapid and simple. The batch of stain will be good with the first try.

2)The staining procedure in some instances is shorter than when using aceto-carmine.

3)The stain shows a high degree of specificity for nuclear structures and gives better results than aceto-carmine when used on certain plant tissues.

4)A minimum number of cells is lost in making the slides permanent when using polyvinyl alcohol mounting medium as the slide and cover slip are run through only one solution prior to mounting.

5)The mounting medium dries rapidly and this shortens the time required before critical examination of the permanent mounts can be made.     

Histological, Chromatographic and Spectrophotometric Studies of Toluidine Blue

Chromatographic analysis of commercial batches of toluidine blue shows these to be dye mixtures. Histologically, some samples were found to be poor metachromatic dyes. These unsatisfactory stains contained blue dyes with little or no metachromatic properties as well as a metachromatic fraction. On the other hand, contaminating dyes in histologically satisfactory samples had poor staining qualities and hence did not interfere with the color produced by the metachromatic fraction.

Chromatographic fractionation of different commercial batches of toluidine blue yielded identical, homogeneous metachromatic dyes. These purified dyes had a peak absorption at 615 mμ in contrast to that of purified azure A whose peak absorption was at 622.5 mμ.     

The Germicidal Effect of Staining Solutions

Gentian violet, crystal violet and carbol fuchsin applied to cover slip preparations for one minute will destroy the majority of non-spore-forming bacteria and yeasts, tho they can not be relied upon to do this consistently and in all cases.

The Gram staining procedure is more effective and non-spore-formers were never found to survive this process.

Methylene blue stains exert very little if any germicidal power and most organisms survived them readily. India ink was totally ineffective.

Several species of yeasts and yeast-like molds were killed in every instance by the Gram stain, gentian violet, crystal violet and carbol fuchsin, but survived both Loeffler's methylene blue and a plain aqueous solution of methylene blue.     

A Consideration of French's Test of Basic Fuchsin for Endo's Medium

In describing a method of testing for the return of color in decolorized fuchsin for use in Endo Medium, French states that variations in hydrogen ion concentration fail to influence the appearance of color in this medium.

Duplications of this test were made using alcoholic and aqueous solutions of fuchsin and both sodium sulfite and sodium bisulfite as decolorizing agents.

In the decolorized alcoholic solutions of fuchsin the color failed to reappear when formalin was added, but a small amount of a weak solution of lactic acid caused the color to return.

Alcoholic solutions of fuchsin failed to decolorize in sodium bisulfite solutions until a few drops of NaOH were added. The color, then, reappeared immediately.

Solutions of peptones to which fuchsin had been added were substituted for the original fuchsin solution. Alcoholic and aqueous solutions of fuchsin were added to equal amounts of a 1% peptone solution. The peptone solutions varied in their hydrogen ion concentration and the results showed that those which were neutral decolorized readily while the more acid solutions were but partially decolorized.

Fuchsin decolorized according to results found in this test, was not satisfactory in the Endo medium, especially in the case of the aqueous solutions of fuchsin.

Experiments which were carried on by other workers and checked with this method all indicated that some acid is necessary to secure the restoration of color.     

Basic Fuchsin as an Indicator in Endo's Medium

The writer has made an investigation of various samples of basic fuchsin for use in the Endo medium for differentiating the bacteria of the colon-typhoid group. Various different concentrations of the fuchsin samples have been used in making the media. The conclusions are as follows:

American made fuchsins differ markedly in their alcohol solubility properties. They contain materials which are very readily soluble in 95% alcohol, but which are precipitated by sodium sulphite.

This precipitation may be prevented by increasing the dilution of the fuchsin in alcohol.

In order to secure more dependable results in the use of decolorized basic fuchsin as an indicator in Endo Agar, it is advisable to test the fuchsin in different dilutions in alcohol in order to secure a completely decolorized solution. It is also advisable to carefully test those fuchsins which decolorize only in high dilutions with a known organism in Endo agar before relying on it as a satisfactory indicator for the presence of sewage organisms.     

The Mechanism of the Gram Reaction. III. Solubilities of Dye-Iodine Precipitates and Further Studies of Primary Dye Substitutes

Solubilities of dye-iodine precipitates in alcohol and in aqueous safranin solution were determined by direct solubility methods and by photocolorimetric methods. It was found that, increasing precipitate solubility in alcohol or safranin solution gave decreasing differentiation between Gram-positive and Gram-negative bacteria. Dyes which did not stain the cells well as a primary stain did not give good Gram stains, regardless of the solubilities of their precipitates. Some dyes (typified by methylene blue) which gave relatively alcohol-insoluble iodine precipitates gave inferior Gram differentiation because these precipitates were readily soluble in the safranin counterstain.

Solubilities of precipitates of crystal violet and various iodine substitutes were determined photocolorimetrically. The ability of a substance to replace iodine in the Gram stain correlated with its ability to give a precipitate which was only slightly soluble in alcohol and relatively insoluble in aqueous safranin solution.

It was concluded that the usual Gram reagents are not truly specific for the differentiation. Any dye and mordant could be used if the dye was deeply colored, stained the cells well, and if the precipitate of dye and mordant was only slightly soluble in alcohol and relatively insoluble in the counterstain. These factors, combined with those influencing differences in cell membrane permeability, constitute the most important factors in the Gram stain differentiation.

Studies were made concerning the ability of dyes to substitute for crystal violet in the Gram procedure. Of 29 dye samples reported on here for the first time none proved to be good substitutes for crystal violet.     

The “Dispersion Staining” Method for the Selective Coloration of Tissue

A method has been developed for the selective coloration of fixed tissue without the use of dyes. Microtome sections of formalin-fixed material are mounted under a cover glass in a mixture of two liquids such as diethylene glycol monobutyl ether with cin-namaldehyde and examined with the dark-field microscope. The refractive index of the liquid used for mounting must be of high dispersion and equal or close to the index of the specimen.

Tissue elements, dependent on their refractive index, whether slightly lower, the same as, or slightly above the mounting medium appear colored in shades of blue, red or yellow.

The optical principles involved in this optical dispersion method are similar to those involved in the production of colored light by the Christiansen filter.     

A Spectrophotometry Analysis of Tissue Staining

By comparing spectral absorption curves of representative staining solutions and of substances stained with these solutions it is shown that information may be obtained regarding chemical changes associated with the staining process. The stains used in these determinations were acid fuchsin, anilin blue, azo-carmine G, basic fuchsin, eosin Y, orange G, picric acid and Sudan IV. The substrates stained were gelatin, tendon, blood plasma, thymus gland and fat.

Aqueous basic fuchsin and fuchsin-sulfurous reagent to which formalin was added (Setoff reaction) are different stains. The spectral absorption curves for staining solutions and substances stained with the solutions were comparable. Within the limitations of the spectrophotometry methods and stains employed, there was no evidence of significant chemical alteration in the chromophore radicals of the stains associated with the process of tissue staining.     

Cytological Methods for Crepis Species

Root tips of Crepis species are fixed in La Cour's “2BE” and dehydrated thru a butyl alcohol series. They are stained in 1% crystal violet for 1 hour, with chromic acid and iodine as pre-and post-staining mordants, respectively, and passed thru dehydrating alcohols containing picric acid and ammonium hydroxide. Differentiation is done in clove oil. The method is rapid; the chromosomes are dark purple; the centromere is not stained; and the cytoplasm is clear. By further controlled destaining the hetero-chromatic segments within the chromosomes may be located.

Pollen mother cells are fixed in acetic alcohol (1:4) and squashed in aceto-carmine. A method is described for making semi-permanent preparations mounted in diaphane.

Pollen grains are mounted in lacto-phenol with acid fuchsin or anilin blue W. S. as the dye.     

Improving the Technic of the Feulgen Stain

A study has been made of the Feulgen stain, in which the staining fluid is a decolorized basic fuchsin. Particular attention has been given to the variation in behavior of different fuchsin samples, the reagent to be employed in decolorizing the dye, the acidity of solutions, and the value of several counter-stains. A modified procedure is suggested, the details of which are given in the paper. The principle modifications of earlier procedures which are recommended are as follows: the use of a specially purified pararosanilin as a dye; the employment of K₂S₂O₅ instead of NaHSO₃ as a decolorizing agent; and counterstaining with fast green in the case of plant tissue or with orange G for animal material.     

Standardization of the Feulgen-Schiff technique

Summary Four fuchsin analogues (Pararosaniline, Rosaniline, Magenta II and New Fuchsin) usually found in Basic Fuchsin have been applied as chemically pure dyes to the Feulgen-technique. Total nuclear absorption and wavelength of the absorption maximum were measured by microspectrophotometry in Feulgen stained cytological and plastic embedded histological liver samples, and in lymphocyte nuclei in human peripheral blood smears; absorption spectra of Feulgen stained DNA-polyacrylamide films were determined by spectrophotometry. The grey value distribution of tetraploid liver cell nuclei was calculated with an image analyzer. The staining characteristics of the pure dyes were compared to commercial fuchsin samples from various suppliers. Reverse phase thin layer chromatography was used for characterization and qualitative separation of commercial batches.Pure fuchsin analogues were all equally suitable for Feulgen staining: with respect of staining intensity all pure fuchsin dyes gave nearly identical results with a bathochromic shift of the absorption maximum from Pararosaniline to New Fuchsin of about 8 m.Differences in staining results observed among the commercial dyes were due to varying dye content, contamination with an acridine-like fluorescent compound or simply mislabelling of samples. Pure Pararosaniline is recommended for a standard Feulgen technique.