An investigation of aldehyde fuchsin staining of unoxidized insulin

Aldehyde fuchsin is a standard stain for the secretion granules of pancreatic B cells. The participation of either insulin or proinsulin in aldehyde fuchsin staining is in dispute. There is some evidence that permanganate oxidized insulin is stained by aldehyde fuchsin. Aldehyde fuchsin staining of unoxidized insulin has not been investigated adequately despite excellent staining results with tissue sections. Unoxidized insulin and proinsulin suspended by electrophoresis in polyacrylamide gels were fixed with Bouin's fluid and placed in aldehyde fuchsin for one hour. Because the unoxidized proteins were not stained by aldehyde fuchsin, it was concluded that neither insulin or proinsulin are responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections. A series of controlled experiments was undertaken to test the effects of fixatives, oxidation and destaining procedures on aldehyde fuchsin staining of insulin, proinsulin and other proteins immobilized in polyacrylamide gels. It was demonstrated that only oxidized proteins were stained by aldehyde fuchsin and that cystine content of the proteins had no apparent relation to aldehyde fuchsin staining. It was concluded that neither insulin nor proinsulin is likely to be responsible for the intense aldehyde fuchsin staining of unoxidized pancreatic B cell granules in tissue sections.     

Fixative-Stain Sequences for Selective Demonstration of Juxtaglomerular Cells

The effects of 31 fixatives, containing alcohol, acids, formalin and metallic salts, and representing many of the standard fixatives, were observed for selectivity and intensity of staining of juxtaglomerular granules in mouse kidney. Four staining methods: 1:400,000 aqueous methyl violet 2B; Bowie's ethyl violet-Biebrich scarlet; 1:200,000 aldehyde fuchsin; and periodic acid-Schiff were used. Fixatives containing HgCl₂, trichloroacetic acid or formalin were found to be the most satisfactory for subsequent staining of the granules.     

Basic Fuchsin in Acid Alcohol: A Simplified Alternative to Schiff Reagent

The use of Schiff reagent to demonstrate polysaccharides (after prior periodic oxidation) and nucleic acids (after prior acid hydrolysis) is unnecessary since the same results are obtained by substituting a 20 min staining in a 0.5% w/v solution of basic fuchsin in acid alcohol (ethanol-water-concentrated HC1, 80:20:1) followed by a rinse in alcohol. The shade of the basic fuchsin staining is a little yellower than that achieved with Schiff reagent but the selectivity, light fastness, response to different fixatives, and to prior histo-chemical blocking of the tissue section were much the same for the two methods. The need for prior oxidation or hydrolysis and the inhibitory effect of aldehyde blocking techniques indicate that basic fuchsin, like Schiff reagent, reacts with aldehyde groups. Infrared studies indicate that for cellulose the reaction product is an azomethine.     

The Nature of Mycobacterial Acid-Fastness

Phenol is not essential to acid-fast staining, for it will occur in the absence of phenol where such lipoid-soluble basic dyes as night blue, Victoria blue B or Victoria R are used; it is essential for acid-fast staining with water soluble basic dyes such as basic fuchsin. When phenol is added to the staining solution, such water soluble basic dyes behave in effect like their lipid-soluble counterparts. The loss of mycobacterial acid-fastness with carbolfuchsin after bromination or chromation indicates that this phenomenon is related to the presence of unsaturated lipids in the bacterial cells. Within the cells these acid-fast lipids are bound in such a way that they are easily removed from all mycobacteria by hot dilute HCl; from leprosy bacilli alone they are easily removed with hot pyridine. From the results of various blocking reactions it appears that carboxyl and especially hydroxyl groups of these cellular lipids are essential to the acid-fast reaction of mycobacteria.     

Histochemistry of protein-bound disulphide groups in the duct secretory granules of the rat submandibular gland

Synopsis The existence of disulphide groups in the granules of the secretory portion of the ducts of rat submandibular glands has been demonstrated with methods that reveal thiol groups formed after reducing the disulphide groups first. Disulphide groups were also demonstrated with cationic dyes by staining the cysteic acid residues obtained after oxidation with permanganate. Alcian Blue at pH 3.0 was used for this purpose. Two kinds of granules, characterized by their reactions with Alcian Blue at different pH levels, were apparent in differing stages of the same secretion.     

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.     

Keratin in the Egg Shells of Amphistomes; Histochemical Differentiation from Quinonetanned Protein in Other Trematoda

Various combinations of the oxidation method for demonstrating keratin in shell material of amphistomes were tried. Acidified permanganate worked more efficiently than performic and peracetic acids, and Alcian blue and aldehyde fuchsin excelled other basic dyes for subsequent staining. For the permanganate-Alcian blue reaction, sections of material fixed in Susa or Bouin were oxidized in 0.3% permanganate in 0.3% H₂SO₄ for 5 min., decolourized in 1% oxalic acid, stained in 3% Alcian blue in 2 N H₂SO₄ and counterstained with eosin. The shell globules stained a deep blue. For permanganate aldehyde fuchsin staining, the sections were stained in aldehyde fuchsin for 1 hr, after oxidation with permanganate. The shell globules then stained a deep magenta. The catechol and fast red reactions were negative in amphistomes and the specimens lack the characteristic amber colour due to quinone tanning.     

Specificity and Sensitivity of Insulin Staining by Aldehyde Fuchsin, Pseudoisocyanin and Toluidine Blue

Aldehyde fuchsin, pseudoisocyanin and toluidine blue, histochemical dyes reported to be specific for insulin-containing granules of the pancreatic beta cell, were applied to insulin fixed in polyacrylamide gel by disc electrophoresis. Two major and four minor bands were resolved as demonstrated by staining with amidoschwarz; only the two major bands, were stained by aldehyde fuchsin. The addition of serum did not affect this reaction. Serum or insulin components gave no metachromatic reactions to the other stains. Under the conditions applied, aldehyde fuchsin is the only one of these dyes specific for insulin in this, system, but this stain is not sufficiently sensitive to detect normal serum levels of the hormone.     

The nature of mycobacterial acid-fastness.

Phenol is not essential to acid-fast staining, for it will occur in the absence of phenol where such lipoid-soluble basic dyes as night blue, Victoria blue B or Victoria R are used; it is essential for acid-fast staining with water soluble basic dyes such as basic fuchsin. When phenol is added to the staining solution, such water soluble basic dyes behave in effect like their lipid-soluble counterparts. The loss of mycobacterial acid-fastness with carbol-fuchsin after bromination or chromation indicates that this phenomenon is related to the presence of unsaturated lipids in the bacterial cells. Within the cells these acid-fast lipids are bound in such a way that they are easily removed from all mycobacteria by hot dilute HCl; from leprosy bacilli alone they are easily removed with hot pyridine. From the results of various blocking reactions it appears that carboxyl and especially hydroxyl groups of these cellular lipids are essential to the acid-fast reaction of mycobacteria.     

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.     

Aldehyde-fuchsin: historical and chemical considerations.

The staining mechanisms of Gomori's aldehyde-fuchsin are not yet fully understood. It seemed therefore timely to review the history of this dye class in context with current dye and aldehyde chemistry. In 1861 Lauth treated basic fuchsin with acetaldehyde. This dye became known as Aldehyde Blue, but consisted of violet and blue dyes. Schiff (1866) studied several aldehyde-fuchsins; these compounds contained two molecules of dye and three molecules of aldehyde. Acetaldehyde-fuchsin prepared according to Schiff's directions showed staining properties similar to those of Gomori's aldehyde-fuchsin. This dye class was soon superseded by new dyes more suitable for textile dyeing, and chemical investigations of aldehyde-fuchsins ceased around the turn of the century. Gomori's aldehyde-fuchsin has been regarded as a Schiff base. However, according to chemical data, low molecular aliphatic aldehydes and aromatic amines tend to form condensation products. Correlations of chemical and histochemical observations suggest such processes during aging of dye solutions. Models of dimers and polymers of aldehyde-fuchsin could be built without steric hindrance. The nature of the bonds formed by various components of aldehyde-fuchsin solutions is not clear. However, cystine in proteins, e.g. in basement membranes, apparently does not play a role in the binding of aldehyde-fuchsin by unoxidized Carnoy- or methacarn-fixed sections.     

Atrial specific granules of the rat heart: light microscopic staining and histochemical reactions.

An investigation was carried out to determine general staining and histochemical properties of rat atrial specific granules. It was found that these granules may be demonstrated using aldehyde fuchsin after pretreatments which involve oxidation or thiosulfation. This new way of demonstrating atrial granules is compared to other staining methods in terms of sensitivity and selectivity as well as to the nature of reactive groups that may be involved in the staining reactions. No lipid or carbohydrate were detected histochemically. Overall assessment of reactions suggests that atrial granules are a site of storage for a protein or polypeptide. Some of the tests indicate that these may contain tryptophan and sulfur-containing amino acids.     

Aldehyde-fuchsin: Historical and chemical considerations

Summary The staining mechanisms of Gomori's aldehyde-fuchsin are not yet fully understood. It seemed therefore timely to review the history of this dye class in context with current dye and aldehyde chemistry. In 1861 Lauth treated basic fuchsin with acetaldehyde. This dye became known as Aldehyde Blue, but consisted of violet and blue dyes. Schiff (1866) studied several aldehyde-fuchsins; these compounds contained two molecules of dye and three molecules of aldehyde. Acetaldehyde-fuchsin prepared according to Schiff's directions showed staining properties similar to those of Gomori's aldehyde-fuchsin. This dye class was soon superseded by new dyes more suitable for textile dyeing, and chemical investigations of aldehyde-fuchsins ceased around the turn of the century. Gomori's aldehyde-fuchsin has been regarded as a Schiff base. However, according to chemical data, low molecular aliphatic aldehydes and aromatic amines tend to form condensation products. Correlations of chemical and histochemical observations suggest such processes during aging of dye solutions. Models of dimers and polymers of aldehyde-fuchsin could be built without steric hindrance. The nature of the bonds formed by various components of aldehyde-fuchsin solutions is not clear. However, cystine in proteins, e.g. in basement membranes, apparently does not play a role in the binding of aldehyde-fuchsin by unoxidized Carnoy- or methacarn-fixed sections.     

The Mechanism of the Gram Reaction I. The Specificity of the Primary Dye

Dyes of all major types were tested for their suitability as the primary dye in the Gram stain. When a counterstain was not used, some dyes of all types were found to differentiate Gram-positive from Gram-negative organisms. When a counterstain was used, these dyes were found to vary greatly in their suitability. Those dyes found to be good substitutes for crystal violet were: Brilliant green, malachite green, basic fuchsin, ethyl violet, Hoffmann's violet, methyl violet B, and Victoria blue R. All are basic triphenylmethane dyes. Acid dyes were generally not suitable. Differences in the reaction of Gram-positive and Gram-negative cells to Gram staining without the use of iodine were observed and discussed but a practical differentiation could not be achieved in this manner. Certain broad aspects of the chemical mechanism of dyes in the gram stain are discussed.     

Stain Solubilities Part 1. Data in the Literature

The rather meager data found in the literature concerning the solubilities of the dyes used as biological stains is reviewed. Solubility data have been found concerning the following dyes: picric acid, martius yellow, crystal ponceau, methyl orange, tropaeolin O, orange II, Bismarck brown, Congo red, auramine, malachite green, fuchsin, methyl violet, gentian violet, crystal violet, methyl green, diphenylamine blue, aurin, corallin, phenolphthalein, flluorescein, eosin Y, iodo-eosin, methylene blue, alizarin, indigo carmine, and carmine. Much of this information is of questionable reliability. The writer is investigating the matter and his original data are to appear in subsequent papers.     

Stain Solubilities Part 1. Data in the Literature

The rather meager data found in the literature concerning the solubilities of the dyes used as biological stains is reviewed. Solubility data have been found concerning the following dyes: picric acid, martius yellow, crystal ponceau, methyl orange, tropaeolin O, orange II, Bismarck brown, Congo red, auramine, malachite green, fuchsin, methyl violet, gentian violet, crystal violet, methyl green, diphenylamine blue, aurin, corallin, phenolphthalein, flluorescein, eosin Y, iodo-eosin, methylene blue, alizarin, indigo carmine, and carmine. Much of this information is of questionable reliability. The writer is investigating the matter and his original data are to appear in subsequent papers.     

Effects of fuchsin variants in aldehyde fuchsin staining

Aldehyde fuchsin stains pancreatic B cell granules, hypophyseal basophils, goblet cell mucins, gastric chief cells, hyaline cartilage, and elastica. Neither the chemical structure of aldehyde fuchsin nor its staining mechanism is known. This study was undertaken to clarify the role of the fuchsin component of aldehyde fuchsin in its staining reaction. The major findings of this investigation include: 1) single N-methylation of the fuchsin molecule abolishes staining of unoxidized pancreatic B cells, although it does not prevent reaction of fuchsin with paraldehyde; 2) aldehyde fuchsin is probably a Schiff base condensation product of pararosaniline and acetaldehyde; 3) a Schiff base structure alone cannot account for aldehyde fuchsin staining of unoxidized pancreatic B cells; 4) a fully potent aldehyde fuchsin is possibly a Tris-Schiff base derivative of pararosaniline.     

Staining properties of aldehyde fuchsin analogs.

This investigation was designed to clarify the role of the aldehyde component of aldehyde fuchsin in its staining reactions. Several aldehyde fuchsin analogs were prepared by using different aldehydes. The staining quality of these analogs and pararosaniline-HCl was compared with that of aldehyde fuchsin prepared with paraldehyde in the usual way. The major findings of this investigation include: 1) Aldehyde fuchsin staining of nonoxidized pancreatic B cells requires a stain prepared with either paraldehyde or acetaldehyde. 2) An aldehyde moiety is required for aldehyde fuchsin staining of strong tissue anions. 3) Staining of elastic tissue with aldehyde fuchsin analogs resembles staining of strong tissue anions more than staining of nonoxidized pancreatic B cells. Possible reaction mechanisms of aldehyde fuchsin with tissue substrates are discussed.     

Only aldehyde fuchsin made from pararosanilin stains pancreatic B cell granules and elastic fibers in unoxidized microsections: problems caused by mislabelling of certain basic fuchsins

The most distinctive property of aldehyde fuchsin is its staining of certain nonionic proteins and peptides in unoxidized cells and tissues. These substances include granules of pancreatic islet B cells, elastic fibers and hepatitis B surface antigen. Aldehyde fuchsin made from two different basic fuchsins, each certified by the Biological Stain Commission and labelled C.I. (Colour Index) No. 42500 (pararosanilin), did not stain pancreatic B cells at all. Stain Commission's records and retesting showed that each of the "faulty" basic fuchsins was not pararosanilin, but rosanilin, whose Colour Index number is 42510. These basic fuchsins were labelled with the wrong Colour Index number when packaged. Additional basic fuchsins were coded by V.M.E. and tested by R.W.M. for their capacity to make satisfactory aldehyde fuchsins. Only certain of these aldehyde fuchsins stained unoxidized pancreatic islet B cells. The same aldehyde fuchsins stained elastic fibers strongly. Each basic fuchsin whose aldehyde fuchsin was judged satisfactory proved to be pararosanilin. Aldehyde fuchsin solutions made from other basic fuchsins stained elastic fibers only weakly and did not stain pancreatic B cells at all in unoxidized sections. Each basic fuchsin whose aldehyde fuchsin was unsatisfactory proved to be rosanilin. It appears that only aldehyde fuchsin made from pararosanilin stains unoxidized pancreatic B cell granules dependably. We found that basic fuchsins from additional lots of Commission-certified pararosanilin and rosanilin were also labelled with incorrect Colour Index numbers when packaged. Steps were taken to prevent recurrences of such mislabelling which has made it difficult until now to correlate differences in the properties of pararosanilin and rosanilin. A table is provided of all basic fuchsins that have been certified by the Biological Stain Commission since 1963 when they began the practice of subdesignating basic fuchsins according to whether they are pararosanilins or nonpararosanilins. The consumer can readily determine from the certification number on the label the correct subdesignation of any Commission-certified basic fuchsin listed here. Until now, mislabelling of some lots of pararosanilin as rosanilin and vice-versa has confused and frustrated the users of basic fuchsins in other applications such as the carbol fuchsin staining of tubercle bacilli and certain cytochemical tests, e.g. esterase and acid phosphatase, that utilize hexazotized pararosanilin as a coupling reagent. Consumers experiencing trouble with any Commission-certified dye should look to the Biological Stain Commission for help. This is an important reason for purchasing, whenever possible, only Biological Stain Commission certified dyes.     

Chemical structures and staining mechanisms of Weigert's resorcin-fuchsin and related elastic fiber stains

Chemical properties of Weigert's resorcin-fuchsin, orcinol-new fuchsin, Sheridan's crystal violet and their resorcinol-free analogues were investigated using reverse-phase and gel filtration chromatography, electrophoresis, and visible light spectroscopy. Their staining properties were also studied. It was concluded that 1) the staining components of Weigert's resorcin-fuchsin, orcinol-new fuchsin and their resorcinol-free analogues are all indamine oligomers, 2) resorcinol is required for the production of Sheridan's crystal violet, the staining components of which consist of crystal violet substituted by varying numbers of resorcinyl substituents, 3) the staining components of all preparations are cationic (i.e., basic) dyes, 4) iron is present in staining solutions as the tetrachloroferrate anion (FeCl4-) and not as Fe or as a dye-chelate, and 5) since even the smallest Weigert's resorcin-fuchsin, orcinol-new fuchsin or Sheridan's crystal violet component has a conjugated bond number of 32, the observed staining of elastic fibers is only as expected.