Anisotropic staining of apurinic acid with toluidine blue.

Using normal rat liver imprints, studies were carried out on the effects of histone extraction and the formation of aldehyde groups from deoxyribose on anisotropic toluidine blue staining of depurinized DNA after sodium bisulfite treatment. The anisotropic effect of bisulfite was found to be determined by binding of bisulfite ions to the aldehyde groups of apurinic acid which, together with free phosphate groups of DNA ensure coparallel attachment of the dye molecules. It was also shown that at pH 5.0 toluidine blue binds with both the phosphate and aldehyde groups of apurinic acid, to give anisotropic staining.     

Influence of some aldehyde blocking agents on staining of depurinized DNA with cationic dyes.

Rat liver, spleen and Walker carcinosarcoma imprints were subjected to depurinizing Feulgen hydrolysis and then treated with blocking agents of aldehyde groups. Such blockators as sodium bisulfite and hydroxylamine which multiplay additionally anionic groups in DNA and intensify the reactions with cationic dyes, ensuring anisotropic staining. Hydrazine lowers the binding of carionic dyes to DNA, instead phenylhydrazine, completely blocks both aldehyde and phosphate groups. When the imprints were treated with 2.4-dinitrophenylhydrazine, aldehyde and phosphate groups of apurinic acid were blocked, and DNA staining by cationic dyes occurred only on account of nitrogroups of the blocking agents which have been used. The staining reaction of cationic dyes after the use of anionogenic blocking agents of aldehyde groups is prospective not only for revealing DNA but also for several other compounds with natural or potential aldo- and ketogroups. However the reaction with phenylhydrazine can serve as a staining without removal of DNA prior to staining as an optional procedure.     

Studies on the molecular arrangement of RNA in tissues with a selective topo-optical reaction of RNA.

Selective demonstration of RNA in tissues was achieved by treating tissue sections with potassium permanganate followed by bisulfite and toluidine blue at pH 1.0 (PBT reaction). It is suggested that this reaction is due to aldehyde groups which are formed by the oxidative cleavage of the pyrimidine rings of RNA which can be selectively demonstrated using bisulfite-toluidine blue as the aldehyde reagent. The specificity of the reaction was tested after RNAase treatment, after acid hydrolysis, and on pure RNA droplets. The aldehyde nature of the reacting groups was checked, after permanganate oxidation, by Schiff's leucofuchsin reagent, and by aldehyde blocking reactions. Two types of intracellular molecular arrangement of RNA molecules could be distinguished by polarization optics after application of the PBT reaction: 1) The strong birefringence, dichroism and metachromatic staining of membrane-bound RNA in ergastoplasm of pancreas, liver and plasma cells indicate a linear (planar) molecular order of RNA molecules on the surface of the membranes, and 2) the isotropic, basophilic staining of RNA not organized in membrane structures (Nissl substance, nucleoli) suggest a random distribution of their dye binding sites.     

Studies on the molecular arrangement of RNA in tissues with a selective topo-optical reaction of RNA

Summary Selective, demonstration of RNA in tissues was achieved by treating tissue sections with potassium permanganate followed by bisulfite and toluidine blue at pH. 1.0 (PBT reaction). It is suggested that this reaction is due to aldehyde groups which are formed by the oxidative cleavage of the pyrimidine rings of RNA which can be selectively demonstrated using bisulfite-toluidine blue as the aldehyde reagent.The specificity of the reaction was tested after RNAase treatment, after acid hydrolysis, and on pure RNA droplets. The aldehyde nature of the reacting groups was checked, after permanganate oxidation, by Schiff's leucofuchsin reagent, and by aldehyde blocking reactions.Two types of intracellular molecular arrangement of RNA molecules could be distinguished by polarization optics after application of the PBT reaction: 1) The strong birefringence, dichroism and metachromatic staining of membrane-bound RNA in ergastoplasm of pancreas, liver and plasma cells indicate a linear (planar) molecular order of RNA molecules on the surface of the membranes, and 2) the isotropic, basophilic staining of RNA not organized in membrane structures (Nissl substance, nucleoli) suggest a random distribution of their dye binding sites.     

Investigation of the anisotropy of glycocalyx stained with 1.9-dimethyl methylene blue and N,N'-diethylpseudoisocyanine chloride (author's transl)]

In the present study the anisotropic staining of the erythrocyte membrane with 1.9-dimethyl methylene blue and N,N'-diethylpseudoisocyanine chloride was studied and simultaneously compared with the toluidine blue topo-optical staining. The difference between anisotropic toluidine blue and 1.9-dimethyl methylene blue staining, except after KMnO4-oxidation, was only of quantitative nature. On the contrary, striking differences were observed between N,N'-diethylpseudoisocyanine chloride staining, and toluidine blue or 1.9-dimethyl methylene blue staining. Enzymatic and chemical degradation resulted the disappearance of N,N'-diethylpseudoisocyanine chloride staining. Following these treatment membrane birefringence could be restored by aldehyde bisulfate and/or KMnO4-oxidation, while the N,N'-diethylpseudoisocyanine chloride staining was restored only after KMnO4-oxidation. After methylation or acetylation the membrane birefringence disappears, while after KMnO4-oxidation both topo-optical reactions return. The digitonin reaction brought about a rearrangement of the glycocyalyx components. The results draw attention to the spatial orientation of the glycoprotein of the erythrocyte membrane. The role of glycocalyx in the three topo-optical reactions was thus clearly demonstrated.     

The oxidative generation of sulfonic acid groups in neuromelanin and lipofuscin in the human brain

Sulfonic acid groups were oxidatively generated in the soluble lipid-free lipofuscin component of neuromelanin of human substantia nigra and in lipofuscin of human inferior olive. Exposure of these oxidized, intraneuronal pigments to low pH Alcian blue or aldehyde fuchsin demonstrated an intensity of staining that related to the type of oxidant and the conditions of its use. Utilization of the following oxidants generated increasingly strong staining reactions as signified by the following sequence; periodic acid under mild conditions, bromine in carbon tetrachloride, hydrogen peroxide, periodic acid under drastic conditions, potassium permanganate followed by oxalic acid, hydrogen peroxide followed by bromine in carbon tetrachloride, potassium permanganate followed by metabisulfite or bisulfite, and performic acid. Neither Alcian blue nor aldehyde fuchsin revealed oxidatively generated aldehyde as judged by 1) their failure or near failure to stain inferior olive lipofuscin following mildly applied periodic acid, and 2) the increase in staining intensity, from moderate to strong, displayed by the soluble lipid-free lipofuscin component of neuromelanin and by inferior olive lipofuscin when potassium permanganate was followed by a rinse with metabisulfite or bisulfite in place of one with oxalic acid.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82--for euchromatic arms--and 0.85--for centromeric heterochromatin--were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

Summary The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes showed higher electron density than control chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82 — for euchromatic arms — and 0.85 — for centromeric heterochromatin — were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

Modification of the method for staining DNA with basic dyes]

The author studied the mechanisms and the applicability in histochemistry of the sodium bisulfate treatment with subsequent toluidine and methylene blue staining after Felgen's hydrolysis. Bisulfite treatment proved to increase the reaction intensity 11/2-fold; the stain is bound stoichiometrically. Toludidine blue results in a metachromatic and anisotropic staining of the cell nuclei. The method is recommended as a sensitive test for DNA in cytochemical investigations and for the study of dichroism of the DNA-containing structures.     

Untersuchungen über die anisotrope Toluidinblaufärbung der Glykokalyx

Zusammenfassung An der Erythrocytenmembran wird die Beziehung zwischen anisotroper Toluidinblaufärbung und Membranstruktur untersucht.Enzymatischer oder chemischer Abbau der Glykokalyx stört die topo-optische Färbung. Eine Abschwächung wird auch durch Digitoninbehandlung Glutaraldehyd-fixierter Zellen erzielt. Durch Chloroform-Methanol-Inkubation wird die anisotrope Toluidinblaufärbung gelöscht, aber sie kann nach Aldehyd-Bisulfitbildung wieder nachgewiesen werden. An agglutinierten Erythrocyten ist die Wirkung einer Chloroform-Methanol-Behandlung stark eingeschränkt. Die reversibel kollabierte Glykokalyx zeigt keine topo-optische Färbung.Die Befunde werden als Hinweis auf die Bedeutung der räumlichen Orientierung der Glykoproteine an der Zelloberfläche gedeutet. Störungen im Aufbau der Glykokalyx durch Hydrolyse bzw. Verlust oder durch Umverteilung von Komponenten verändern die Bedingungen für die anisotrope Toluidinblaufärbung. Eingriffe an der Lipidschicht können mit solchen Veränderungen einhergehen; für die Interkalation von Farbstoffmolekülen in die Lipidschicht ergab sich jedoch kein Anhalt. Die topo-optische Färbung mit Toluidinblau wird auf Grund dieser Ergebnisse als geeignetes Verfahren zur Untersuchung der Glykokalyx von Erythrocyten (und vermutlich auch anderer Zellen) angesehen.

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Investigations on the glycocalyx with toluidin blue staining

Summary The study was concerned with the molecular structure of the erythrocyte membrane and its anisotropic staining with toluidine blue.Enzymatic or chemical degradation impairs the topo-optical staining. Decreased anisotropy results also from digitonin treatment of glutaraldehyde fixed cells. Incubation in a mixture of chloroform and methanol abolishes the anisotropic staining with toluidine blue, but it has been restored by the aldehyde bisulfite-procedure. The efficacy of a treatment with chloroform-methanol is greatly reduced in the case of agglutinated erythrocytes. The reversibly collapsed glycocalyx is devoid of topo-optical staining.The findings refer to the spatial orientation of glycoproteins at the cell surface. Degradation or loss and rearrangement, respectively, change the glycocalyx structure and likewise deteriorate the conditions for the anisotropic staining. Alterations of the lipid layer of the membrane may result in similar effects. There was, however, no indication of an intercalation into the lipid layer of dyestuff molecules. In conclusion, the topo-optical toluidine blue staining is considered a powerful method aiding studies of the glycocalyx of erythrocytes (and presumably of other types of cells too).

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Mit Unterstützung durch einen Forschungsauftrag des Ministeriums für Wissenschaft und Technik der DDR     

Nuclear stains with soluble metachrome metal mordant dye lakes. The effect of chemical endgroup blocking reactions and the artificial introduction of acid groups into tissues.

Following our study on the effect of deoxyribonucleic acid (DNA) extraction on nuclear staining with soluble metal mordant dye lakes covering 29 dye lakes we chose a series of lakes representing the three groups: (1) readily prevented by DNA removal, (2) weakened by DNA extraction but not prevented, (3) unaffected by DNA removal, for application of other endgroup blockade reactions. The lakes selected were alum and iron hematoxylins, iron alum and ferrous sulfate galleins, Fe2+ gallo blue E, iron alum celestin blue B, iron alum fluorone black and the phenocyanin TC-FeSO4 sequence. Azure A with and without an eosin B neutral stain, was used as a simple cationic (and anionic) dye control. Methylation was less effective than with simple cationic dyes, but did weaken celestin blue, gallo blue E and phenocyanin Fe2+ nuclear stains. These dyes also demonstrate other acid groups: acid mucins, cartilage matrix, mast cells, central nervous corpora amylacea and artificially introduced carboxyl, sulfuric and sulfonic acid groups. Alum hematoxylin stained cartilage weakly and demonstrated sulfation and sulfonation sites. The iron galleins, iron fluorone black and acid iron hematoxylin do not. A pH 4 iron alum hematoxylin gave no staining of these sites; an alum hematoxylin acidified with 1% 12 N HCl gave weaker results. Deamination prevented eosin and orange G counterstains but did not impair nuclear stains with any of the mordant dye lakes. The simple acetylations likewise did not alter mordant dye nuclear staining, the Skraup reagent gave its usual sulfation effect on other tissue elements, but did not alter nuclear stains by mordant dyes. The mordant dyes do not bind to periodic acid engendered aldehyde sites and p-toluidine/acetic acid and borohydride aldehyde blockades did not alter mordant dye lake nuclear staining. Nitration by tetranitromethane, which blocks azo coupling of tyrosine residues, did not alter nuclear staining by the mordant dye lakes. Benzil at pH 13, which prevents the beta-naphthoquinone-4-Na sulfonate (NQS) arginine reaction and the Fullmer reaction of basic nucleoprotein, did not affect iron gallein, iron or alum hematoxylin stains of nuclei or lingual keratohyalin.     

Unmasking of Proteins by in Vitro Methylation of Rat Liver Rna During Azo Dye Carcinogenesis

In liver parenchyma of rats fed the azo dye 4-dimethylaminoazobenzene cytoplasmic ribonucleic acid (RNA) stains intensely with toluidine blue in sites of neoplastic transformation and hepatomas. With the mercury-bromphenol blue method, the staining intensity of proteins was found to be much weaker in these areas than in surrounding tissue. A 4 hr treatment at 60 C in a mixture of methanol and HCI completely abolished the increased staining of RNA with toluidine blue, but restored protein stainability with bromphenol blue in preneoplastic foci and tumors; the staining intensity of proteins was then comparable to that in surrounding liver. These results suggest that proteins were masked by the RNA responsible for hyperbasophilia, and that in vitro addition of methyl groups to such RNA is equal in effect to RNase extraction which was previously found to unmask cytoplasmic proteins.     

Acid polysaccharide content of frog rod outer segments determined by metachromatic toluidine blue staining

Sulfonation of periodate-oxidized vicinal hydroxyl groups on a polysaccharide backbone allows binding of toluidine blue (aldehyde bisulfite-toluidine blue or ABT staining) with a concurrent metachromatic shift of the dye's absorption peak from 630 nm (monomer) to 580 nm (isolated dimer interaction at vicinal sulfonate groups) or 540 nm (dye polymer interaction). A molar absorptivity of 2.358 +/- 0.134 X 10(4) at 540 nm for polymeric toluidine blue O chloride (TB) aggregates was determined by spectrophotometry of TB bound to hyaluronic acid (HA) and sulfonated glycogen (SG) in water. Microspectrophotometry of ABT stained frog rod outer segments (FROS) showed spectra similar to TB in aqueous HA and SG solutions with absorbances corresponding to 0.063 M dye bound to sugar. Given two dye molecules bound per sugar residue and a rhodopsin concentration of 3.25 mM in FROS, the above indicates 10 stainable sugars per rhodopsin are contained in these cells. Half of these sugars are sensitive to hyaluronidase digestion implying 5 glycosaminoglycan (GAG) repeating units and 5 stainable oligosaccharide sugar residues per rhodopsin in FROS. The GAGs in FROS appear to be primarily HA. Birefringence measurements at 475 nm indicate that this HA and the oligosaccharide of rhodopsin are anisotropically oriented in these cells.     

A method for the stabilization of toluidine blue vital staining for histological and ultrastructural studies

A method previously developed to stabilize methylene blue vital staining has been applied to toluidine blue, a basic dye with a closely related chemical structure commonly used as a vital stain for the screening of oral and esophageal lesions.The stain was made stable by adding 1% sodium silicotungstate to an aldehyde fixative (formaldehyde or glutaraldehyde). Sections were prepared for light and electron microscopy.     

Staining Mitochondria in Saccharomyces cerevisiae

After testing various procedures (amidoblack 10B, acid fuchsin-methyl blue, Luxol fast blue MBS-phloxine, toluidine blue O, Jams green B and pinacyanol), three stains can be recommended for staining both types of mitochondria (globose and threadlike) in the cells of Saccharomyces cerevisiae: (1) 0.1% solution of amidoblack 10B in citrate buffer (pH 3.0) for 10 min; (2) 0.01% solution of toluidine blue O in phosphate buffer (pH 6.0) for 30 min; (3) 0.01% solution of Janus green B in distilled water (pH 5.6) for 30 min. The latter stain is most specific because its staining reaction depends upon the action of the mitochondrial enzyme cytochrome c oxidase. Yet, low concentrations and short incubation periods must be applied to avoid poisoning of the cell metabolism.     

Acid polysaccharide content of frog rod outer segments determined by metachromatic toluidine blue staining

Summary Sulfonation of periodate-oxidized vicinal hydroxyl groups on a polysaccharide backbone allows binding of toluidine blue (aldehyde bisulfite-toluidine blue or ABT staining) with a concurrent metachromatic shift of the dye's absorption peak from 630 nm (monomer) to 580 nm (isolated dimer interaction at vicinal sulfonate groups) or 540 nm (dye polymer interaction). A molar absorptivity of 2.358±0.134×10⁴ at 540 nm for polymeric toluidine blue O chloride (TB) aggregates was determined by spectrophotometry of TB bound to hyaluronic acid (HA) and sulfonated glycogen (SG) in water. Microspectrophotometry of ABT stained frog rod outer segments (FROS) showed spectra similar to TB in aqueous HA and SG solutions with absorbances corresponding to 0.063 M dye bound to sugar. Given two dye molecules bound per sugar residue and a rhodopsin concentration of 3.25 mM in FROS, the above indicates 10 stainable sugars per rhodopsin are contained in these cells. Half of these sugars are sensitive to hyaluronidase digestion implying 5 glycosaminoglycan (GAG) repeating units and 5 stainable oligosaccharide sugar residues per rhodopsin in FROS. The GAGs in FROS appear to be primarily HA. Birefringence measurements at 475 nm indicate that this HA and the oligosaccharide of rhodopsin are anisotropically oriented in these cells.Supported by NIH grants EY00012, EY07035 and EY01583     

The effect of clupein on anisotropy and basophilia of polytene chromosomes.

When polytene chromosomes are subjected to a clupein treatment, their properties of basophilia and anisotropy are affected. The basophilia is deeply reduced, except in the nucleolar zones, puffs and sites of RNA accumulation. On the other hand, the chromosome birefringence increases. The phenomenon of anomalous dispersion of birefringence usually observed on polytene chromosomes stained with toluidine blue solutions turns into a normal negative dispersion of birefringence, when staining is preceded by clupein treatment. It is concluded that the clupein molecules attach orderly and preferentially to sequential DNA phosphates unbound to chromosome proteins, accentuating DNA anisotropic characteristics. The clupein molecules appear not attaching to RNA phosphates.     

The effect of clupeinon anisotropy and basophilia of polytene chromosomes

Summary When polytene chromosomes are subjected to a clupein treatment, their properties of basophilia and anisotropy are affected. The basophilia is deeply reduced, except in the nucleolar zones, puffs and sites of RNA accumulation. On the other hand, the chromosome birefringence increases. The phenomenon of anomalous dispersion of birefringence usually observed on polytene chromosomes stained with toluidine blue solutions turns into a normal negative dispersion of birefringence, when staining is preceded by clupein treatment. It is concluded that the clupein molecules attach orderly and preferentially to sequential DNA phosphates unbound to chromosome proteins, accentuating DNA anisotropic characteristics. The clupein molecules appear not attaching to RNA phosphates.     

A Staining Sequence for A, B and D Cells of Pancreatic Islets

Recent investigations strongly suggest the elaboration of a third pancreatic hormone by the D cell and the existence of cells which show the staining properties of both B and D cells. Demonstration of these and all other islet cells in a single section is possible by the following staining sequence: (1) of D cells by silver or toluidine blue, (2) of B cells by pseudoisocyanin, and (3) empirical staining of all islet cells together by aldehyde fuchsin, ponceau de xylidine, acid fuchsin and light green. Difficulties in embedding compact pancreatic tissue can be overcome by dehydrating to 80% ethanol, followed by tetrahydrofurane as the intermediate fluid to paraffin infiltration.     

Induced metachromasia in bull spermatozoa

Summary The availability of sequential DNA phosphates to bind toluidine blue molecules after acid hydrolysis was studied in normally shaped and misshaped spermatozoa from subfertile and highly fertile bulls. The aim was to associate induced spermatozoal metachromasia with infertility. Some few normally and abnormally shaped cells from highly fertile bulls exhibited an induced metachromasia after being treated with 4N HCl for 10–30 min at 25°C prior to staining. Subfertile bulls contained 12 times as many metachromatic spermatozoa as highly fertile animals. The induced toluidine blue metachromasia is suggested as a rapid and simple method for detecting bull spermatozoa bearing an anomalous DNA-protein complex. This nucleoprotein complex was found to be more frequent in subfertile bulls.