Acid alcoholic brilliant cresyl blue stain for gastric and other mucins

Summary Some but not all samples of brilliant cresyl blue (6-methyl-7-dimethylamino-2-phenoxazin chloride) under C. I. No. 51010 in Conn's Biological Stains when dissolved at 1% level in 50–70% alcohol containing 1% concentrated (12 N) hydrochloric acid, stain (in 30 min) a wide variety of human and laboratory animal mucins blue black on an almost unstained background. The mucoprotein of the gastric surface epithelium and of the peptic gland neck cells of several species reacts strongly. A 16 hr 60° C methylation in 0.1 M methyl-sulfuric acid in methanol is required to block the staining of these gastric and some intestinal mucins, while 1–2 hr intervals suffice to prevent the staining of mast cells, cartilage and metachromatic sulfomucins generally. Saponification (1% KOH/70% alcohol, 20min) does not restore staining in either location group, indicating that sulfate mucins are probably reacting in both.Most other basic dyes fail to stain mucins from acid alcohol solutions: azure A, toluidine blue, resorcin blue, orcein, resorufin, azoresorufin brown, azolitmin, lacmoid, gallocyanin, Nile blue, methylene green, pararosanilin, crystal violet, Victoria blue R. Some staining occurred with one of three lots of Victoria blue B, with two lots of Victoria blue 4 R and with one lot each of Bernthsen's methylene violet, elastin violet PR and elastin purple PP.The stain may be preceded by the Feulgen reaction to give red nuclei, or followed by a brief collagen stain in an alcoholic acid fuchsin (0.05–0.1%), picric acid (1.5%) solution.Presented before the Symposium of the Histochemische Gesellschaft in Hamburg, 28. September 1968.Supported by National Cancer Institute Grant No. C-4816, National Institutes of Health.     

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.     

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.     

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.     

Differential Dichrome Staining of Tissue Culture Monolayers: Alternate Dyes and Possible Mechanism

A polyacid-dependent dichrome has been devised which will differentiate epithelial from mesenchymal cells in young dividing primary cultures. Epithelial cells and colonies and nuclei are stained with metanil yellow, the stain is fixed and differentiated with phosphotungstic acid, and the mesenchymal elements are stained with toluidine blue. Several other dyes are tested for substitution in this method. Biebrich scarlet and aniline blue could be substituted for the metanil yellow; Bismarck brown T, Janus green B, crystal violet, and neutral red could be substituted for the basic dye.     

Differential dichrome staining of tissue culture monolayers: alternate dyes and possible mechanism.

A polyacid-dependent dichrome has been devised which will differentiate epithelial from mesenchymal cells in young dividing primary cultures. Epithelial cells and colonies and nuclei are stained with metanil yellow, the stain is fixed and differentiated with phosphotungstic acid, and the mesenchymal elements are stained with toluidine blue. Several other dyes are tested for substitution in this method. Biebrich scarlet and aniline blue could be substituted for the metanil yellow; Bismarck brown T, Janus green B, crystal violet, and neutral red could be substituted for the basic dye.     

The Staining of Brunner's Gland and Other Neutral Mucins by Carmine, Hematoxylin and Orcein in Alkaline Solutions

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

The Staining of Brunner's Gland and Other Neutral Mucins by Carmine,Hematoxylin and Orcein in Alkaline Solutions

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

The staining of Brunner's gland and other neutral mucins by carmine, hematoxylin and orcein in alkaline solutions.

Brunner's glands and other neutral mucins may be stained red, brownish red, and violet, respectively, by carmine, hematoxylin, and orcein from appropriate alkaline solutions. Carmine and hematoxylin in concentrations of 0.2-1% are dissolved in 60-70% alcohol containing 1% potassium carbonate; orcein is used in a 0.2% alcoholic solution of sodium hydroxide. Staining times are 15 to 30 minutes. The stained sections are rinsed in 95% or absolute alcohol prior to xylene and mounting. The staining of these mucins is blocked by mild bromine oxidation. By using alcian blue 0.1% in 3% acetic acid for 5 minutes prior to the above stains, mucins may be characterized in the same preparation as acid, neutral or mixed.     

A Tri-Basic-Dye Stain for Nerve Cells

A new staining method has been developed for the study of nerve cells and Nissl granules which combines three basic dyes, cresylecht violet, toluidine blue and thionin. The use of this tri-basic-dye stain results in finished preparations that are critically stained and permanent. Paraffin sections (4 μ sections preferably) are mounted on slides by the starch medium, deparaffinized and stained by the tribasic staining solution. After differentiation in acidified distilled water, sections are dehydrated, returned to stain solution and again dehydrated, then cleared and mounted in Clarite. Various vertebrate material including normal and pathological human tissues have been stained with this triple dye solution. Especially for pathological material, re-immersion of slides in the staining and 80% alcohol solutions before mounting, differentially intensifies the staining reaction. Fixatives used were 10% formalin, 95% alcohol, Bouin and formalin-Bouin (10% formalin followed by Bouin).     

Staining of depolymerised DNA in mammalian tissues with methyl violet 6B and crystal violet

The paper contains an account of DNA staining with basic dyes; methyl violet 6B and crystal violet in mammalian tissue sections after RNA extraction with cold concentrated phosphoric acid. The study shows that the best staining is obtained at pHs 2.5 and 3.5. Dehydration of stained nuclei is perfect when a mixture of absolute ethanol and n-butanol is used followed by treatment of sections in isoamyl or amyl alcohol. The in situ absorption data of nuclei stained with aqueous solution of methyl violet 6B as well as with crystal violet are also presented. Possible mechanism of staining as well as an explanation for dye-leaching when sections are dehydrated through ethanol are discussed.     

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.     

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.     

The Demonstration of Beryllium Oxide in Paraffin Sections with Chromoxane Stains

Aqueous solutions of the arylmethane dyes Chromoxane pure blue BLD (C.I. No. 43825) and Chromoxane pure blue B (C.I. No. 43830) will stain beryllium oxide. In the presence of EDTA the staining of other metals is masked. As a specific stain for BeO, formol saline fixed paraffin sections are hydrated and stained for 1 hr with either 0.1 gm of pure blue BLD in 100 ml of pH 4.0 Na-acetate buffer or with 0.1 gm of pure blue B in 1 N NaOH adjusted to pH 9.0 with HCl. To mask interference from other metal ions, 9 gm of Na₂-EDTA is added to 100 ml of the stain solution. BeO is stained blue, organic tissue components are either unstained or pink. Results of tests against other materials show that a high degree of specificity may be expected from these dyes. A 1% aqueous solution of neutral red may be used as a counterstain.     

A Cresyl Fast Violet Stain for Bacteria and Fungi in Tissue

The cresyl fast violet staining method was modified to eliminate differentiation. Paraffin sections from tissues fixed in Zenker-formol were stained in a 1% aqueous solution of cresyl fast violet (Chroma), adjusted to pH 3.7 with acetic acid, washed in running tap water, dehydrated and covered. Because basophilia increases with time of fixation or storage in formalin or Kaiserling's fluid, dilution of the dye solution to 0.5-0.1% is recommended for such material. Bacteria, nuclei, Nissl substance, and lipofuscin were colored dark blue; fungi, blue to purple; and cytoplasm and muscle fibers, light blue. Collagen and reticulum fibers were only faintly stained. Thus, microorganisms were easily visible against the lightly colored background. In formalin-fixed material, bile pigment was colored olive green. Because this method does not require differentiation, it gave uniform results even in the hands of different users. Little or no fading was observed in sections stored for more than 2 yr.     

Staining of Keratin and Keratohyalin with the Reactive Dye Levafix Red Violet E-2BL

Demonstration of keratin in Zenker-fired skin and in tissues stored in formalin can be difficult because such material is unsuitable for histochemical studies. A reactive dye, Levafix red violet E-PBL, proved useful for demonstration of keratohyalin and some types of keratin. Formalin-, Zenker- and methacarn-fired sections were pretreated with alkaline alcohol, stained one hour at 60 C in an aqueous solution containing 0.25% Levafix red violet E-2BL plus 0.25% NaC1, rinsed in buffer solution pH 9, dehydrated and mounted. Keratohyalin granules and stratum corneum were colored red violet; hair and tonofibrils remained unstained. In sections prestained with Mayer's acid hemalum, keratohyalin was dark blue. Sulfonated monoazo dyes without reactive groups colored no tissue structures under the conditions of this technic; apparently, Levafix red violet E-2BL is bound via its reactive group. Polarization microscopic studies suggest binding of Levafix red violet E-2BL by an amorphous matrix of keratin. Correlations with chemical data indicate that the staining patterns parallel the distribution of proteins formed in the stratum granulosum.     

Staining of keratin and keratohyalin with the reactive dye levafix red violet E-2BL.

Demonstration of keratin in Zenker-fixed skin and in tissues stored in formalin can be difficult because such material is unsuitable for histochemical studies. A reactive dye, Levafix red violet E-2BL, proved useful for demonstration of keratohyalin and some types of keratin. Formalin-, Zenker- and methacarn-fixed sections were pretreated with alkaline alcohol, stained one hour at 60 C in an aqueous solution containing 0.25% Levafix red violet E-2BL plus 0.25% NaCl, rinsed in buffer solution pH 9, dehydrated and mounted. Keratohyalin granules and stratum corneum were colored red violet; hair and tonofibrils remained unstained. In sections prestained with Mayer's acid hemalum, keratohyalin was dark blue. Sulfonated monoazo dyes without reactive groups colored no tissue structures under the conditions of this technic; apparently, Levafix red violet E-2BL is bound via its reactive group. Polarization microscopic studies suggest binding of Levafix red violet E-2BL by an amorphous matrix of keratin. Correlations with chemical data indicate that the staining patterns parallel the distribution of proteins formed in the stratum granulosum.     

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.     

The demonstration of two acid groups in juxtaglomerular granules with basic triphenyl methane dyes,aldehyde-fuchsin and schiff's reagent

Summary Oxidation and bromination of mouse kidney JG cell-granules result in the production of cysteic acid from cystine; cysteic acid is capable of taking up rapidly and selectively certain basic triphenyl methane dyes including aldehyde fuchsin at lower pH levels.After treatment with periodic acid, bromine and hydrochloric acid, the JG granules or the nuclear chromatin also take up the basic triphenyl methane dyes (including aldehyde fuchsin) which contain amino groups, probable as a result of the production of aldehyde groups. Basic triphenyl methane lacking amino groups does not react with aldehydes.Some substance present in JG granules could be stained by aldehyde fuchsin after prior oxidation; HCl methyl violet 2B was taken up both with or without prior oxidation. Only strong methylation completely abolished these affinities which were restored after demethylation. These reactions are attributed to cystine.The staining of JG granules with dilute aldehyde fuchsin and dilute methyl violet 2B is not affected by oxidation, bromination, aldehyde blocking and hydrolysis; these reactions are abolished by mild methylation, but restored by subsequent saponification. These staining properties are due to the presence of carboxylic acid in JG granules.The positive PAS reaction of JG granules is due to the presence of 1.2-glycol in the same granules.     

Neuron Staining by Basic Dyes Versus Basic Metal-Dye Complexes; Differences Shown by Histochemical Blocking Reactions

Various blocking procedures were applied to sections of paraffin-embedded, formalin-fixed cat spinal cord. Treated sections and untreated controls were stained with cresyl violet acetate or gallocyanine-chrome alum. Although both dyes have been said to stain by simple salt formation it was found that staining was affected differently for each dye by the blocking procedures, and also that staining of neuron nuclei differed in the controls. In these, the cresyl violet acetate stained only the nucleoli within the nucleoplasm whereas gallocyanine-chrome alum stained much more material of unknown composition and function. It is proposed that if cresyl violet acetate and other basic dyes stain by salt linkage, and can be specific for nucleic acid and other highly acid materials, then gallocyanine and other basic metal dye complexes can not be specific for nucleic acid and do not stain by a simple salt linkage.